Elastic substantially linear ethylene polymers

ABSTRACT

Elastic ethylene polymers are disclosed which have processability similar to highly branched low density polyethylene (LDPE), but the strength and toughness of linear low density polyethylene (LLDPE). The polymers have processing indices (PI&#39;s) less than or equal to 70 percent of those of a comparative linear ethylene polymer and a critical shear rate at onset of surface melt fracture of at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a traditional linear ethylene polymer at about the same I 2  and M w /M n . The novel polymers can also have from about 0.01 to about 3 long chain branches/1000 total carbons and have higher low/zero shear viscosity and lower high shear viscosity than comparative linear ethylene polymers. The novel polymers can also be characterized as having a melt flow ratio, I 10 /I 2 , ≧5.63, a molecular weight distribution, M w /M n , defined by the equation: M w /M n ≦(I 10 /I 2 )−4.63, a critical shear stress at onset of gross melt fracture greater than about 4×10 6  dyne/cm 2 , and a single DSC melt peak between −30 C. and 150 C.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No. 08/778,586 filed Jan. 3, 1997, now U.S. Pat. No. 6,136,937, which is a continuation-in-part of U.S. application Ser. No. 08/044,426 filed Apr. 7, 1993, now U.S. Pat. No. 5,380,810, which is a divisional of U.S. application Ser. No. 07/776,130 filed Oct. 15, 1991, now U.S. Pat. No. 5,272,236. This application is also a continuation-in-part of U.S. application Ser. No. 08/166,497 filed Dec. 13, 1993, now abandoned, which is a divisional of U.S. application Ser. No. 07/939,281 filed Sep. 2, 1992 which is now U.S. Pat. No. 5,278,272.

FIELD OF THE INVENTION

This invention relates to elastic substantially linear ethylene polymers having improved processability, e.g., low susceptibilty to melt fracture, even under high shear stress conditions. Such substantially linear ethylene polymers have a critical shear rate at the onset of surface melt fracture substantially higher than, and a processing index substantially less than, that of a linear polyethylene at the same molecular weight distribution and melt index.

BACKGROUND OF THE INVENTION

Molecular weight distribution (MWD), or polydispersity, is a well known variable in polymers. The molecular weight distribution, sometimes described as the ratio of weight average molecular weight (M_(w)) to number average molecular weight (M_(n)) (i.e., M_(w)/M_(n)) can be measured directly, e.g., by gel permeation chromatography techniques, or more routinely, by measuring I₁₀/I₂ ratio, as described in ASTM D-1238. For linear polyolefins, especially linear polyethylene, it is well known that as M_(w)/M_(n) increases, I₁₀/I₂ also increases.

John Dealy in “Melt Rheology and Its Role in Plastics Processing” (Van Nostrand Reinhold, 1990) page 597 discloses that ASTM D-1238 is employed with different loads in order to obtain an estimate of the shear rate dependence of melt viscosity, which is sensitive to weight average molecular weight (M_(w)) and number average molecular weight (M_(n)).

Bersted in Journal of Applied Polymer Science Vol. 19, page 2167-2177 (1975) theorized the relationship between molecular weight distribution and steady shear melt viscosity for linear polymer systems. He also showed that the broader MWD material exhibits a higher shear rate or shear stress dependency.

Ramamurthy in Journal of Rheology, 30(2), 337-357 (1986), and Moynihan, Baird and Ramanathan in Journal of Non-Newtonian Fluid Mechanics, 36, 255-263 (1990), both disclose that the onset of sharkslin (i.e., surface melt fracture) for linear low density polyethylene (LLDPE) occurs at an apparent shear stress of 1-1.4×10⁶ dyne/cm², which was observed to be coincident with the change in slope of the flow curve. Ramamurthy also discloses that the onset of surface melt fracture or of gross melt fracture for high pressure low density polyethylene (HP-LDPE) occurs at an apparent shear stress of about 0.13 MPa (1.3×10⁶ dyne/cm). Ramnamurthy also discloses that “the corresponding shear stresses (0.14 and 0.43 MPa) for linear polyethylenes are widely separated.” However, these LLDPE resins are linear resins, and are believed to be those made by Union Carbide in their UNIPOL process (which uses conventional Ziegler-Natta catalysis which results in a heterogeneous comonomer distribution). The LLDPE is reported in Tables I and II to have a broad M_(w)/M_(n) of 3.9. The melt fracture tests conducted by Ramamurthy were in the temperature range of 190 to 220 C. Furthermore, Ramamurthy reports that the onset of both surface and gross melt fracture (for LLDPE resins) are “. . . essentially independent of MI (or molecular weight), melt temperature, die diameter (0.5-2.5 mm), die length/diameter ratio (2-20), and the die entry angle (included angle: 60-180 degrees).”

Kalika and Denn in Journal of Rheology, 31, 815-834 (1987) confirmed the surface defects or sharkskin phenomena for LLDPE, but the results of their work determined a critical sheer stress at onset of surface melt fracture of 0.26 MPa, significantly higher than that found by Ramamurthy and Moynihan et al. Kalika and Denn also report that the onset of gross melt fracture occurs at 0.43 MPa which is consistent with that reported by Ramamurthy. The LLDPE resin tested by Kalika and Denn was an antioxidant-modified (of unknown type) UNIPOL LLDPE having a broad M_(w)/M_(n) of 3.9. Kalika and Denn performed their melt fracture tests at 215 C. However, Kalika and Denn seemingly differ with Ramamurthy in the effects of their L/D of the rheometer capillary. Kalika and Denn tested their LLDPE at L /D's of 33.2, 66.2, 100.1, and 133.1 (see Table 1 and FIGS. 5 and 6).

International Patent Application (Publication No. WO 90/03414) published Apr. 5, 1990 to Exxon Chemical Company, discloses linear ethylene interpolymer blends with narrow molecular weight distribution and narrow short chain branching distributions (SCBDs). The melt processibility of the interpolymer blends is controlled by blending different molecular weight interpolymers having different narrow molecular weight distributions and different SCBDS.

Exxon Chemical Company, in the Preprints of Polyolefins VII International Conference, page 45-66, Feb. 24-27 1991, disclose that the narrow molecular weight distribution (NMWD) resins produced by their EXXPOL™ technology have higher melt viscosity and lower melt strength than conventional Ziegler resins at the same melt index. In a recent publication, Exxon Chemical Company has also taught that NMWD polymers made using a single site catalyst create the potential for melt fracture (“New Specialty Linear Polymers (SLP) For Power Cables,” by Monica Hendewerk and Lawrence Spenadel presented at IEEE meeting in Dallas, Tex., September, 1991). In a similar vein, in “A New Family of Linear Ethylene Polymers Provides Enhanced Sealing Performance” by Dirk G. F. Van der Sanden and Richard W. Halle, (February 1992 Tappi Journal), Exxon Chemical Company has also taught that the molecular weight distribution of a polymer is described by the polymers melt index ratio (i.e., I₁₀/I₂) and that their new narrow molecular weight distribution polymers made using a single site catalyst are “linear backbone resins containing no functional or long chain branches.”

U.S. Pat. No. 5,218,071 (Canadian patent application 2,008,315-A) to Mitsui Petrochemical Industries, Ltd., teaches ethylene copolymers composed of structural units (a) derived from ethylene and structural units (b) derived from alpha-olefins of 3-20 carbons atoms, said ethylene copolymers having [A] a density of 0.85-0.92 g/cm³, [B] an intrinsic viscosity as measured in decalin at 135 C of 0.1 -10 dl/g, [C] a ratio (M_(w)/M_(n)) of a weight average molecular weight (M_(w)) to a number average molecular weight (M_(n)) as measured by GPC of 1.2-4, and [D] a ratio (MFR₁₀/MFR₂) of MFR₁₀ under a load of 10 kg to MFR₂ under a load of 2.16 kg at 190 C. of 8-50, and being narrow in molecular weight distribution and excellent in flowability. However, the ethylene copolymers of U.S. Pat. No. '071 are made with a catalysis system composed of methylaluminoxane and ethylenebis(indenyl)hafnium dichloride (derived from HfCl₄ containing 0.78% by weight of zirconium atoms as containates). It is well known that mixed metal atom catalyst species (such as hafnium and zirconium in U.S. Pat. No. '071) polymerizes copolymer blends, which are evidence by multiple melting peaks. Such copolymer blends therefore are not homogeneous in terms of their branching distribution.

WO 85/04664 to BP Chemicals Ltd. teaches a process for the thermo-mechanical treatment of copolymers of ethylene and higher alpha-olefins of the linear low density polyethylene type with at least one or more organic peroxides to produce copolymers that are particularly well suited for extrusion or blow-molding into hollow bodies, sheathing, and the like. These treated copolymers show an increased flow parameter (I₂₁/I₂) without significantly increasing the M_(w)/M_(n). However, the novel polymers of the present invention have long chained branching and obtained this desirable result without the need of a peroxide treatment.

U.S. Pat. No. 5,096,867 discloses various ethylene polymers made using a single site catalyst in combinations with methyl aluminoxane. These polymers, in particular Example 47, have extremely high levels of aluminum resulting from catalyst residue. When these aluminum residues are removed from the polymer, the polymer exhibits gross melt fracture at a critical shear stress of less than 4×10⁶ dyne/cm².

All of the foregoing patents, applications, and articles are herein incorporated by reference.

Previously known narrow molecular weight distribution linear polymers disadvantageously possessed low shear sensitivity or low I₁₀/I₂ value, which limits the extrudability of such polymers. Additionally, such polymers possessed low melt elasticity, causing problems in melt fabrication such as film forming processes or blow molding processes (e.g., sustaining a bubble in the blown film process, or sag in the blow molding process etc.). Finally, such resins also experienced melt fracture surface properties at relatively low extrusion rates thereby processing unacceptably.

SUMMARY OF THE INVENTION

A new class of homogeneous ethylene polymers have now been discovered which have long chain branching and unusual but desirable bulk properties. These new polymers include both homopolymers of ethylene and interpolymers of ethylene and at least one alpha-olefin. Both the homo- and interpolymers have long chain branching, but the interpolymers have short chain branching in addition to the long chain branching. The short chain branches are the residue of the alpha-olefins that are incorporated into the polymer backbone or in other words, the short chain branches are that part of the alpha-olefin not incorporated into the polymer backbone. The length of the short chain branches is two carbon atoms less than the length of the alpha-olefin comonomer. The short chain branches are randomly, i.e. uniformitly, distributed throughout the polymer as opposed to heterogeneously branched ethylene/alpha-olefin interpolymers such as conventional Zeigler LLDPE.

These novel ethylene polymers have a shear thinning and ease of processability similar to highly branched low density polyethylene (LDPE), but with the strength and toughness of linear low density polyethylene (LLDPE). These novel ethylene polymers can also be characterized as “substantially linear” polymers, whereby the bulk polymer has an average of up to about 3 long chain branches/1000 total carbons or in other words, at least some of the polymer chains have long chain branching. The novel substantially linear ethylene polymers are distinctly different from traditional Ziegler polymerized heterogeneous polymers (e.g., LLDPE) and are also different from traditional free radical/high pressure polymerized LDPE. Surprisingly, the novel substantially linear ethylene polymers are also different from linear homogeneous ethylene polymers having a uniform comonomer distribution, especially with regard to processability.

These novel ethylene polymers, especially those with a density greater than or equal to about 0.9 g/cm³ are characterized as having:

a) a melt flow ratio, I₁₀/I₂, ≧5.63,

b) a molecular weight distribution, M_(w)/M_(n), defined by the equation:

M _(w) /M _(n) ≦( I ₁₀ /I ₂)−4.63,

c) a critical shear stress at onset of gross melt fracture greater than about 4×10⁶ dyne/cm², and

d) a single melt peak as determined by differential scanning calorimetry (DSC) between −30 and 150 C.

The novel ethylene polymers can also be characterized as having:

a) a melt flow ratio, I₁₀/I₂, ≧5.63,

b) a molecular weight distribution, M_(w)/M_(n), defined by the equation:

M _(w) /M _(n)≦(I₁₀/I₂)−4.63,

c) a critical shear rate at onset of surface melt fracture at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a linear ethylene polymer with an I₂, M_(w)/M_(n), and density each within ten percent of the novel ethylene polymer, and

d) a single melt peak as determined by differential scanning calorimetry (DSC) between −30 and 150 C.

In another aspect, the novel ethylene polymers, especially those having a density greater than or equal to about 0.9 g/cm³, are characterized as having:

a) a melt flow ratio, I₁₀/I₂, ≧5.63, and

b) a molecular weight distribution, M_(w)/M_(n) of from about 1.5 to about 2.5,

c) a critical shear stress at onset of gross melt fracture greater than about 4×10⁶ dyne/cm², and

d) a single melt peak as determined by differential scanning calorimetry (DSC) between −30 and 150 C.

In still another aspect, the novel ethylene polymers are characterized as having:

a) a melt flow ratio, I₁₀/I₂, ≧5.63,

b) a molecular weight distribution, M_(w)/M_(n) of from about 1.5 to about 2.5,

c) a critical shear rate at onset of surface melt fracture of at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a linear ethylene polymer with an I₂, M_(w)/M_(n), and density each within ten percent of the novel ethylene polymer, and

d) a single melt peak as determined by differential scanning calorimetry (DSC) between −30and 150 C.

The substantially linear ethylene polymers can also be characterized as having a critical shear rate at onset of surface melt fracture of at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a linear ethylene polymer having an I₂, M_(w)/M_(n) and density each within ten percent of the substantially linear ethylene polymer.

In still another aspect the novel polymer can be characterized as a substantially linear ethylene bulk polymer having:

(a) and average of about 0.01 to about 3 long chain branches/1000 total carbons,

(b) a critical shear stress at onset of gross melt fracture of greater than about 4×10⁶ dyne/cm², and

(c) a single DSC melt peak between −30 and 150 C.

The substantially linear ethylene bulk polymer can also be characterized as having:

(a) an average of about 0.01 to about 3 long chain branches/1000 total carbons,

(b) a critical shear rate at onset of surface melt fracture of at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a linear ethylene polymer having an I₂, M_(w)/M_(n) and density each within ten percent of the substantially linear ethylene bulk polymer, and

(c) a single DSC melt peak between −30 and 150 C.

In still another aspect, the ethylene polymer can be characterized as a substantially linear ethylene bulk polymer having:

(a) average of about 0.01 to about 3 long chain branches/l000 total carbons,

(b) a melt flow ratio, I₁₀/I₂, ≧5.63,

(c) a molecular weight distribution, M_(w)/M_(n), from about 1.5 to about 2.5, and

(d) a single DSC melt peak between −30 and 150 C.

The novel ethylene polymers, especially the substantially linear ethylene polymers, also have a processing index (PI) less than or equal to about 70 percent of the PI of a linear ethylene polymer at about the same I₂, M_(w)/M_(n), and density each within ten percent of the novel ethylene polymer.

Compositions comprising the novel ethylene polymer and at least one other natural or synthetic polymer are also within the scope of the invention.

Elastic substantially linear ethylene polymers comprising ethylene homopolymers or an interpolymer of ethylene with at least one C₃-C₂₀ alpha-olefin copolymers are especially preferred.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic representation of a polymerization process suitable for making the polymers of the present invention.

FIG. 2 plots data describing the relationship between I₁₀/I₂ and M_(w)/M_(n), for two examples of the invention, and for some comparative examples.

FIG. 3 plots the shear stress versus shear rate for an Example of the invention and for a Comparative Example, described herein.

FIG. 4 plots the shear stress versus shear rate for an Example of the invention and for a Comparative Example, described herein.

FIG. 5 plots the heat seal strength versus heat seal temperature of film made from Examples of the invention, and for Comparative Examples, described herein.

FIG. 6 graphically displays dynamic shear viscosity data for an elastic substantially linear ethylene polymer of the present invention and for a comparative linear polymer made using single site catalyst technology.

FIG. 7 graphically displays I₁₀/I₂ ratio as a function of ethylene concentration in the polymerization reactor for ethylene/propene substantially linear copolymers of the invention.

FIG. 8 graphically displays the melting curves for a comparative polymer made according to U.S. Pat. No. 5,218,071 (Mitsui).

FIG. 9 graphically displays the structural characteristics of a traditional heterogeneous Ziegler polymerized LLDPE copolymers, a highly branched high pressure-free radical LDPE, and a novel substantially linear ethylene/alpha-olefin copolymer of the invention.

DETAILED DESCRIPTION OF THE INVENTION

The term “linear” as used herein means that the ethylene polymer does not have long chain branching. That is, the polymer chains comprising the bulk linear ethylene polymer have an absence of long chain branching, as for example the traditional linear low density polyethylene polymers or linear high density polyethylene polymers made using Ziegler polymerization processes (e.g., U.S. Pat. No. 4,076,698 (Anderson et al.)), sometimes called heterogeneous polymers. The term “linear” does not refer to bulk high pressure branched polyethylene, ethylene/vinyl acetate copolymers, or ethylene/vinyl alcohol copolymers which are known to those skilled in the art to have numerous long chain branches. The term “linear” also refers to polymers made using uniform branching distribution polymerization processes, sometimes called homogeneous polymers, including narrow MWD (e.g. about 2) made using single site catalysts. Such uniformly branched or homogeneous polymers include those made as described in U.S. Pat. No. 3,645,992 (Elston) and those made using so-called single site catalysts in a batch reactor having relatively high ethylene concentrations (as described in U.S. Pat. No. 5,026,798 (Canich) or in U.S. Pat. No. 5,055,438 (Canich)) or those made using constrained geometry catalysts in a batch reactor also having relatively high olefin concentrations (as described in U.S. Pat. No. 5,064,802 (Stevens et al.) or in EP 0 416 815 A2 (Stevens et al.)). The uniformly branched/homogeneous polymers are those polymers in which the comonomer is randomly distributed within a given interpolymer molecule or chain, and wherein substantially all of the interpolymer molecules have the same ethylene/comonomer ratio within that interpolymer, but these polymers too have an absence of long chain branching, as, for example, Exxon Chemical has taught in their February 1992 Tappi Journal paper. For example, FIG. 9 shows the structural differences among conventional heterogeneously branched LLDPE, homogeneously branched linear LLDPE, highly branched high pressure, free radical LDPE, and the homogeneously branched substantially linear ethylene polymers of the present invention.

The term “substantially linear” as used means that the bulk polymer is substituted, on average, with about 0.01 long chain branches/1000 total carbons (including both backbone and branch carbons) to about 3 long chain branches/1000 total carbons. Preferred polymers are substituted with about 0.01 long chain branches/1000 total carbons to about 1 long chain branches/1000 total carbons, more preferably from about 0.05 long chain branches/1000 total carbons to about 1 long chain branched/1000 total carbons, and especially from about 0.3 long chain branches/1000 total carbons to about 1 long chain branches/1000 total carbons.

As used herein, the term “backbone” refers to a discrete molecule, and the term “polymer” or “bulk polymer” refers in the conventional sense to the polmer as formed in a reactor. For the polymer to be a “substantially linear” polymer, the polymer must have at least enough molecules with long chain branching such that the average long chain branching in the bulk polymer is at least an average of about 0.01/1000 total carbons.

The term bulk polymer means the polymer which results from the polymerization process and, for the substantially linear polymers, includes molecules having both an absence of long chain branching, as well as molecules having long chain branching. Thus a bulk polymer includes all molecules formed during polymerization. It is understood that, for the substantially linear polymers, not all molecules have long chain branching, but a sufficient amount do such that the average long chain branching content of the bulk polymer positively affects the melt rheology (i.e., the melt fracture properties).

Long chain branching (LCB) is defined herein as a chain length of at least one (1) carbon less than the number of carbons in the comonomer, whereas short chain branching (SCB) is defined herein as a chain length of the same number of carbons in the residue of the comonomer after it is incorporated into the polymer molecule backbone. For example, an ethylene/1-octene substantially linear polymer has backbones with long chain branches of at least seven (7) carbons in length, but it also has short chain branches of only six (6) carbons in length.

Long chain branching can be distinguished from short chain branching by using ¹³C nuclear magnetic resonance (NMR) spectroscopy and to a limited extent, e.g. for ethylene homopolymers, it can be quantified using the method of Randall (Rev. Macromol. Chem. Physl., C29 (2&3), p. 285-297), the disclosure of which is incorporated herein by reference. However as a practical matter, current ¹³C nuclear magnetic resonance spectroscopy cannot determine the length of a long chain branch in excess of about six (6) carbon atoms and as such, this analytical technique cannot distinguish between a seven (7) carbon branch and a seventy (70) carbon branch. The long chain branch can be as long as about the same length as the length of the polymer back-bone.

U.S. Pat. No. 4,500,648, incorporated herein by reference, teaches that long chain branching frequeny (LCB) can be represented by the equation LCB=b/M_(w) wherein b is the weight average number of long chain branches per molecule and M_(w) is the weight average molecular weight. The molecular weight averages and the long chain branching characteristics are determined by gel permeation chromatography and intrinsic viscosity methods.

Similar to the traditional homogeneous polymers, the substantially linear ethylene/alpha-olefin copolymers of the invention have only a single melting point, as opposed to traditional Ziegler polymerized heterogeneous linear ethylene/alpha-olefin copolymers which have two or more melting points (determined using differential scanning calorimetry (DSC)). Ethylene polymers of this invention are also characterized by a single DSC melting peak between −30 and 150 C. However, those polymers having a density of about 0.875 g/cm³ to about 0.91 g/cm³, the single melt peak may show, depending on equipment sensitivity, a “shoulder” or a “hump” on the low side of the melting peak (i.e. below the melting point) that constitutes less than 12 percent, typically, less than 9 percent, more typically less than 6 percent of the total heat of fusion of the polymer. This artifact is due to intrapolymer chain variations, and it is discerned on the basis of the slope of the single melting peak varying montonically through the melting region of the artifacl Such artifact occurs within 34 C., typically within 27 C., and more typically within 20 C. of the melting point of the single melting peak. The single melting peak is determined using a differential scanning calorimeter standardized with indium and deionized water. The method involves about 5-7 mg sample sizes, a “first heat” to about 150 C. which is held for 4 minutes, a cool down at 10/min. to −30 C. which is held for 3 minutes, and heat up at 10 C/min. to 150 C. for the “second heat” heat flow vs. temperature curve. Total heat of fusion of the polymer is calculated from the area under the curve. The heat of fusion attributable to this artifact, if present, can be determined using an analytical balance and weight-percent calculations.

FIG. 8 displays the melting curves for a polymer of the invention and for a comparative polymer as described in U.S. Pat. No. 5,218,071 (Mitsui). Note that the comparative polymer has two melting peaks (the high melting peak with a shoulder on its high side, i.e. above the second melting point), and this is indicative of the presence of two distinct polymers (as opposed to the melting curve of the invention polymer having only a single melting peak).

The SCBDI (Short Chain Branch Distribution Index) or CDBI (Composition Distribution Branch Index) is defined as the weight percent of the polymer molecules having a comonomer content within 50 percent of the median total molar comonomer content. The CDBI of a polymer is readily calculated from data obtained from techniques known in the art, such as, for example, temperature rising elution fractionation (abbreviated herein as “TREF”) as described, for example, in Wild et al, Journal of Polymer Science, Poly. Phys. Ed., Vol. 20, p. 441 (1982), or as described in U.S. Pat. No. 4,798,081. The SCBDI or CDBI for the substantially linear ethylene polymers of the present invention is typically greater than about 30 percent, preferably greater than about 50 percent, more preferably greater than about 80 percent, and most preferably greater than about 90 percent.

“Melt tension” is measured by a specially designed pulley transducer in conjunction with the melt indexer. Melt tension is the load that the extrudate or filament exerts while passing over the pulley onto a two inch drum that is rotating at the standard speed of 30 rpm. The melt tension measurement is similar to the “Melt Tension Tester” made by Toyoseiki and is described by John Dealy in “Rheometers for Molten Plastics”, published by Van Nostrand Reinhold Co. (1982) on page 250-251. The melt tension of these new polymers is also surprisingly good, e.g., as high as about 2 grams or more. For the novel substantially linear ethylene interpolymers of this invention, especially those having a very narrow molecular weight distribution (i.e., M_(w)/M_(n) from 1.5 to 2.5), the melt tension is typically at least about 5 percent, and can be as much as about 60 percent, greater than the melt tension of a conventional linear ethylene interpolymer having a melt index, polydispersity and density each within ten percent of the substantially linear ethylene polymer.

A unique characteristic of the presently claimed polymers is a highly unexpected flow property where the I₁₀/I₂ value is essentially independent of polydispersity index (i.e. M_(w)/M_(n)). This is contrasted with conventional Ziegler polymerized heterogeneous polyethylene resins and with conventional single site catalyst polymerized homogeneous polyethylene resins having rheological properties such that as the polydispersity index increases, the I₁₀/I₂ value also increases.

The density of the neat ethylene or substantially linear ethylene polymers of this invention, Le. polymers without inorganic fillers and not containing in excess of 20 ppm aluminum from catalyst residue, is measured in accordance with ASTM D-792. The ethylene or substantially linear ethylene polymers are crystalline and/or semi-crystalline polymers, are normally solid at room temperature, and are pelletizable at ambient conditions or at temperatures induced by cooled water. For example, a novel substantially linear ethylene/1-octene copolymer having a density of 0.865 g/cm³ has about 10% crystallinity at room temperature. The minimum density is typically at least about 0.865 g/cm³, preferably at least about 0.870 g/cm³, and more preferably at least about 0.900 g/cm³. The maximum density typically does not exceed about 0.970 g/cm³, preferably it does not exceed about 0.940 g/cm³, and more preferably it does not exceed about 0.92 g/cm³.

The molecular weight of the ethylene or ethylene/alpha-olefin substantially linear ethylene polymers in the present invention is conveniently indicated using a melt index measurement according to ASTM D-1238, Condition 190 C/2.16 kg (formally known as “Condition (E)” and also known as I₂). Melt index is inversely proportional to the molecular weight of the polymer. Thus, the higher the molecular weight, the lower the melt index, although the relationship is not linear. The melt index for the ethylene or ethylene/alpha-olefin substantially linear ethylene polymers used herein is generally from about 0.01 grams/10 minutes (g/10 min) to about 1000 g/10 min, preferably from about 0.01 g/10 min to about 100 g/10 min, and especially from about 0.01 g/10 min to about 10 g/10 min.

Another measurement useful in characterizing the molecular weight of the substantially linear ethylene polymers is conveniently indicated using a melt index measurement according to ASTM D-1238, Condition 190C/10 kg (formerly known as “Condition (N)” and also known as I₁₀). The ratio of these two melt index terms is the melt flow ratio and is designated as I₁₀/I₂. For the substantially linear ethylene/alpha-olefin polymers of the invention, the I₁₀/I₂ ratio indicates the degree of long chain branching, ie., the higher the I₁₀/I₂ ratio, the more long chain branching in the polymer. Generally, the I₁₀/I₂ ratio of the substantially linear ethylene/′-olefin polymers is at least about 5.63, preferably at least about 7, especially at least about 8, most especially at least about 9 or above. The only limitations on the maximum I₁₀/I₂ ratio are practical considerations such as economics, polymerization kinetics, etc., but typically the maximum I₁₀/I₂ ratio does not exceed about 20, and preferably it does not exceed about 15.

Antioxidants (e.g., hindered phenolics (e.g., Irganox® 1010 made by Ciba Geigy Corp.), phosphites (e.g., Irgafos® 168 made by Ciba Geigy Corp.)), are preferably added to protect the polymer from degradation during thermal processing steps such as pelletization, molding, extrusion, and characterization methods. Other additives to serve special functional needs include cling additives, e.g. PIB, antiblocks, antislips, pigments, fillers. In-process additives, e.g. calcium stearate, water, etc., may also be used for other purposes such as for the deactivation of residual catalyst However, peroxide need not be added to the novel polymers in order for the polymers to exhibit an I₁₀/I₂ independent of the MWD and the melt fracture properties.

Molecular Weight Distribution Determination

The whole interpolymer product samples and the individual interpolymer samples are analyzed by gel permeation chromatography (GPC) on a Waters 150 C. high temperature chromatographic unit equipped with three linear mixed porosity bed columns (available from Polymer Laboratories), operating at a system temperature of 140 C. The solvent is 1,2,4-trichlorobenzene, from which 0.3 percent by weight solutions of the samples are prepared for injection. The flow rate is 1.0 milliliters/minute and the injection size is 200 microliters.

The molecular weight determination is deduced by using narrow molecular weight distribution polystyrene standards (from Polymer Laboratories) in conjunction with their elution volumes. The equivalent polyethylene molecular weights are determined by using appropriate Mark-Houwink coefficients for polyethylene and polystyrene (as described by Williams and Ward in Journal of Polymer Science, Polymer Letters, Vol. 6, (621) 1968) to derive the following equation:

M _(polyethylene) =a*(M_(polystyrene))^(b).

In this equation, a=0.4316 and b=1.0 for polyethylene and polystyrene in 1,2,4-trichlorobenzene. Weight average molecular weight, M_(W), is calculated in the usual manner according to the following formula: M_(w)=Σw_(i)*M_(i), where w_(i) and M_(i) are the weight fraction and molecular weight, respectively, of the i^(th) fraction eluting from the GPC column.

The molecular weight distribution (M_(w)/M_(n)) for the substantially linear ethylene polymers of the invention is generally less than about 5, preferably from about 1.5 to about 2.5, and especially from about 1.7 to about 2.3.

Processing Index Determination

The “rheological processing index” (PI) is the apparent viscosity (in kpoise) of a polymer and is measured by a gas extrusion rheometer (GER). The GER is described by M. Shida, R. N. Shroff and L. V. Cancio in Polym. Eng. Sci., Vol. 17, no. 11, p. 770 (1977), and in “Rheometers for Molten Plastics” by John Dealy, published by Van Nostrand Reinhold Co. (1982) on page 97-99, the disclosures of both of which are incorporated in their entirety herein by reference. The processing index is measured al a temperature of 190 C., at nitrogen pressure of 2500 psig using a 0.0296 inch (752 micrometers) diameter (preferably 0.0143 inch diameter die for high flow polymers, e.g. 50-100 melt index or greater), 20:1 L/D die having an entrance angle of 180 degrees. The GER processing index is calculated in millipoise units from the following equation:

PI=2.15×10⁶ dyne/cm²/(1000×shear rate),

where: 2.15×10⁶ dyne/cm² is the shear stress at 2500 psi, and the shear rate is the shear rate at the wall as represented by the following equation:

32 Q′/(60 sec/min)(0.745)(Diameter×2.54 cm/in)³, where:

Q′ is the extrusion rate (gms/min),

0.745 is the melt density of polyethylene (gm/cm³), and

Diameter is the orifice diameter of the capillary (inches).

The PI is the apparent viscosity of a material measured at apparent shear stress of 2.15×10⁶ dyne/cm².

For the substantially linear ethylene polymers (or ethylene/alpha-olefin copolymers or interpolymers), the PI is less than or equal to 70 percent of that of a conventional linear ethylene polymer (or ethylene/alpha-olefin copolymer or interpolymer) having an I₂, M_(w)/M_(n) and density each within ten percent of the substantially linear ethylene polymer.

An apparent sheer stress vs. apparent shear rate plot is used to identify the melt fracture phenomena over a range of nitrogen pressures from 5250 to 500 psig using the die or GER test apparatus previously described. According to Ramamurthy in Journal of Rheology, 30(2), 337-357, 1986, above a certain critical flow rate, the observed extrudate irregularities may be broadly classified into two main types: surface melt fracture and gross melt fracture.

Surface melt fracture occurs under apparently steady flow conditions and ranges in detail from loss of specular gloss to the more severe form of “sharkskin”. In this disclosure, the onset of surface melt fracture is characterized at the beginning of losing extrudate gloss at which the surface roughness of extrudate can only be detected by 40×magnification. The critical shear rate at onset of surface melt fracture for the substantially linear ethylene polymers is at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a linear ethylene polymer having about the same I₂ and M_(w)/M_(n). Preferably, the critical shear stress at onset of surface melt fracture for the substantially linear ethylene polymers of the invention is greater than about 2.8×10⁶ dyne/cm².

Gross melt fracture occurs at unsteady flow conditions and ranges in detail from regular (alternating rough and smooth, helical, etc.) to random distortions. For commercial acceptability, (e.g., in blown film products), surface defects should be minimal, if not absent The critical shear rate at onset of surface melt fracture (OSMF) and critical shear stress at onset of gross melt fracture (OGMF) will be used herein based on the changes of surface roughness and configurations of the extrudates extruded by a GER For the substantially linear ethylene polymers of the invention, the critical shear stress at onset of gross melt fracture is preferably greater than about 4×10⁶ dyne/cm².

For the processing index determination and for the GER melt fracture determination, the novel ethylene or substantially linear ethylene copolymers are tested without inorganic fillers, and they do not have more than 20 ppm aluminum catalyst residue. Preferably, however, for the processing index and melt fracture tests, the novel ethylene polymers and substantially linear ethylene copolymers do contain antioxidants such as phenols, hindered phenols, phosphites or phosphonites, preferably a combination of a phenol or hindered phenol and a phosphite or a phosphonite.

The Constrained Geometry Catalyst

Suitable constrained geometry catalysts for use herein preferably include constrained geometry catalysts as disclosed in U.S. application Ser. Nos.: 545,403, filed Jul. 3, 1990; 758,654, filed Sep. 12, 1991 now U.S. Pat. No. 5,132,381; 758,660, filed Sep. 12, 1991, and 720,041, filed Jun. 24, 1991. The monocyclopentadienyl transition metal olefin polymerization catalysts taught in U.S. Pat. No. 5,026,798 which is incorporated herein by reference, are also believed to be suitable for use in preparing the polymers of the present invention, so long as the polymerization conditions substantially conform to those of the present invention.

The foregoing catalysts may be further described as comprising a metal coordination complex comprising a metal of groups 3-10 or the Lanthanide series of the Periodic Table of the Elements and a delocaized pi-bonded moiety substituted with a constrain-inducing moiety, said complex having a constrained geometry about the metal atom such that the angle at the metal between the centroid of the delocalized, substituted pi-bonded moiety and the center of at least one remaining substituent is less than such angle in a similar complex containing a similar pi-bonded moiety lacking in such constrain-inducing substituent, and provided further that for such complexes comprising more than one delocalized, substituted pi-bonded moiety, only one thereof for each metal atom of the complex is a cyclic, delocalized, substituted pi-bonded moiety. The catalyst further comprises an activating cocatalysl

Preferred catalyst complexes correspond to the formula:

wherein:

M is a metal of group 3-10, or the Lanthanide series of the Periodic Table of the Elements;

Cp* is a cyclopentadienyl or substituted cyclopentadienyl group bound in an eta⁵ bonding mode to M;

Z is a moiety comprising boron, or a member of group 14 of the Periodic Table of the Elements, and optionally sulfur or oxygen, said moiety having up to 20 non-hydrogen atoms, and optionally Cp* and Z together form a fused ring system;

X independently each occurrence is an anionic ligand group or neutral Lewis base ligand group having up to 30 non-hydrogen atoms;

n is 0, 1, 2, 3, or 4 and is 2 less than the valence of M; and

Y is an anionic or nonanionic ligand group bonded to Z and M comprising nitrogen, phosphorus, oxygen or sulfur and having up to 20 non-hydrogen atoms, optionally Y and Z together form a fused ring system.

More preferably still, such complexes correspond to the formula:

wherein:

R′ each occurrence is independently selected from the group consisting of hydrogen, alkyl aryl silyl, germyl, cyano, halo and combinations thereof having up to 20 non-hydrogen atoms;

X each occurrence independently is selected from the group consisting of hydride, halo, alkyl, aryl, silyl, gernyl, aryloxy, alkoxy, amide, siloxy, neutral Lewis base ligands and combinations thereof having up to 20 non-hydrogen atoms;

Y is —O—, —S—, —NR*—, —PR*—, or a neutral two electron donor ligand selected from the group consisting of OR*, SR*, NR*₂ or PR*₂;

M is as previously defined; and

Z is SiR*₂, CR*₂, SiR*₂SiR*₂, CR*₂CR*₂, CR*═CR*, CR*₂SiR*₂, GeR*₂, BR*, BR*₂;

wherein

R* each occurrence is independently selected from the group consisting of hydrogen, alkyl, aryl, silyl, halogenated ailcyl, halogenated aryl groups having up to 20 non-hydrogen atoms, and mixtures thereof, or two or more R* groups from Y, Z, or both Y and Z form a fused ring system; and n is 1 or 2.

It should be noted that whereas formula I and the following formulas indicate a cyclic structure for the catalysts, when Y is a neutral two electron donor ligand, the bond between M and Y is more.accurately referred to as a coordinate-covalent bond. Also, it should be noted that the complex may exist as a dimer or higher oligomer.

Further preferably, at least one of R′, Z, or R* is an electron donating moiety. Thus, highly preferably Y is a nitrogen or phosphorus containing group corresponding to the formula —N(R″)— or —P(R″)—, wherein R″ is C₁₋₁₀ alkyl or aryl, i.e., an amido or phosphido group.

Most highly preferred complex compounds are amidosilane- or amidoalkanediyl-compounds corresponding to the formula:

wherein:

M is titanium, zirconium or hafnium, bound in an eta⁵ bonding mode to the cyclopentadienyl group;

R′ each occurrence is independently selected from the group consisting of hydrogen, silyl, alkyl, aryl and combinations thereof having up to 10 carbon or silicon atoms;

E is silicon or carbon;

X independently each occurrence is hydride, halo, alkyl, aryl, aryloxy or alkoxy of up to 10 carbons;

m is 1 or 2; and

n is 1 or 2.

Examples of the above most highly preferred metal coordination compounds include compounds wherein the R′ on the amido group is methyl, ethyl, propyl, butyl, pentyl, hexyl, (including isomers), norbornyl, benzyl, phenyl, etc.; the cyclopentadienyl group is cyclopentadienyl, indenyl, tetrahydroindenyl, fluorenyl, octahydrofluorenyl, etc.; R′ on the foregoing cyclopentadienyl groups each occurrence is hydrogen, methyl, ethyl, propyl, butyl, pentyl hexyl, (including isomers), norbornyl benzyl phenyl etc.; and X is chloro, bromo, iodo, methyl ethyl, propyl, butyl, pentyl, hexyl, (including isomers), norbornyl, benzyl, phenyl, etc. Specific compounds include: (tert-butylamido)(tetramethyl-eta⁵-cyclopentadienyl)-1,2-ethanediylzirconium dichloride, (tert-butylarnido)(tetramethyl-eta⁵yclopentadienyl)-1,2-ethanediyltitanium dichloride, (methylamido)(tetramethyl-eta⁵-cyclopentadienyl)-1,2-ethanediyzirconium dichloride, (methylamido)(tetramethyl-eta⁵-cyclopentadienyl)-1,2-ethanediyltitanium dichloride, (ethylamido)(tetramethyl-eta⁵-cyclopentadienyl)-methylenetitanium dichloro, (tertbutylamido)dibenzyl(termethyl-eta⁵-cyclopentadienyl)silanezirconium dibenzyl, (benzylamido)dimethyl-(tetuamelhyl-eta5-cyclopentadienyl)silaneutanium dichloride, (phenylphosphido)dimethyl(tetramethyl-eta⁵-cyclopentadienyl)silanezirconiuum dibenzyl, (tertbutylarnido)dimethyl(tetramethyl-eta⁵-cyclopentadienyl)silanetitanium dimethyl, and the like.

The complexes may be prepared by contacting a derivative of a metal, M, and a group I metal derivative or Grignard derivative of the cyclopentadienyl compound in a solvent and separating the salt byproduct Suitable solvents for use in preparing the metal complexes are aliphatic or aromatic liquids such as cyclohexane, methylcyclohexane, pentane, hexane, heptane, tetrahydrofuran, diethyl ether, benzene, toluene, xylene, ethylbenzene, etc., or mixtures thereof.

In a preferred embodiment, the metal compound is MX_(n+1), i.e., M is in a lower oxidation state than in the corresponding compound, MX_(n+2) and the oxidation state of M in the desired final complex. A noninterfering oxidizing agent may thereafter be employed to raise the oxidation state of the metal The oxidation is accomplished merely by contacting the reactants utilizing solvents and reaction conditions used in the preparation of the complex itself. By the term “noninterfering oxidizing agent” is meant a compound having an oxidation potential sufficient to raise the metal oxidation state without interfering with the desired complex a formation or subsequent polymerization processes. A particularly suitable noninterfering oxidizing agent is AgCl or an organic halide such as methylene chloride. The foregoing techniques are disclosed in U.S. Ser. No. 545,403, filed Jul. 3, 1990 and 702,475, filed May 20, 1991, the teachings of both of which are incorporated herein by reference.

Additionally the complexes may be prepared according to the teachings of the copending U.S. application Ser. No. 778,433 entitled: “Preparation of Metal Coordination Complex (I)”, filed in the names of Peter Nickias and David Wilson, on Oct. 15, 1991 and the copending U.S. application Ser. No. 778,432 entitled: “Preparation of Metal Coordination Complex (II)”, filed in the names of Peter Nickias and David Devore, on Oct. 15, 1991, and the patents issuing therefrom, all of which are incorporated herein by reference.

Suitable cocatalysts for use herein include polymeric or oligomeric aluminoxanes, especially methyl aluminoxane, as well as inert, compatible, noncoordinating, ion forming compounds. So called modified methyl aluminoxane (MMAO) is also suitable for use as a cocatalysl One technique for preparing such modified aluminoxane is disclosed in U.S. Pat. No. 5,041,584. Aluminoxanes can also be made as disclosed in U.S. Pat. Nos. 5,218,071; 5,086,024, 5,041,585, 5,041,583, 5,015,749, 4,960,878 and 4,544,762 all of which are incorporated herein by reference. Aluminoxanes, including modified methyl aluminoxanes, when used in the polymerization, are preferably used such that preferably less than about 20 ppm aluminum, especially less than about 10 ppm aluminum, and more preferably less than about 5 ppm alumninum, from catalyst residue remain in the polymer. In order to measure the bulk polymer properties (e.g. PI or melt fracture), aqueous HCl is used to extract the aluminoxane from the polymer. Preferred cocatalysts, however, are inert, noncoordinatina, boron compounds such as those described in EP 520732 which is incorporated herein by reference.

Ionic active catalyst species which can be used to polymerize the polymers described herein correspond to the formula:

wherein:

M is a metal of group 3-10, or the Lanthanide series of the Periodic Table of the Elements;

Cp* is a cyclopentadienyl or substituted cyclopentadienyl group bound in an eta⁵ bonding mode to M;

Z is a moiety comprising boron, or a member of group 14 of the Periodic Table of the Elements, and optionally sulfur or oxygen, said moiety having up to 20 non-hydrogen atoms, and optionally Cp* and Z together form a fused ring system;

X independently each occurrence is an anionic ligand group or neutral Lewis base ligand group having up to 30 non-hydrogen atoms;

n is 0, 1, 2, 3, or 4 and is 2 less than the valence of M; and

A—is a noncoordinating, compatible anion.

One method of making the ionic catalyst species which can be utilized to make the polymers of the present invention involve combining:

a) at least one first component which is a mono(cyclopentadienyl) derivative of a metal of Group 3-10 or the Lanthanide Series of the Periodic Table of the Elements containing at least one substituent which will combine with the cation of a second component (described hereinafter) which first component is capable of forming a cation formally having a coordination number that is one less than its valence, and

b) at least one second component which is a salt of a Bronsted acid and a noncoordinating, compatible anion.

More particularly, the nonordinating, compatible anion of the Bronsted acid salt may comprise a single coordination complex comprising a charge-bearing metal or metalloid core, which anion is both bulky and non-nucleophilic. The recitation “metalloid”, as used herein, includes non-metals such as boron, phosphorus and the like which exhibit semi-metallic characteristics.

Illustrative, but not limiting examples of monocyclopentadienyl metal components (first components) which may be used in the preparation of cationic complexes are derivatives of titanium, zirconium, vanadium, hafnium, chromium, lanthanum, etc. Preferred components are titanium or zirconium compounds. Examples of suitable monocyclopentadienyl metal compounds are hydrocarbyl-substituted monocyclopentadienyl metal compounds such as (tert-butylamido)(tetramethyl-eta⁵-cyclopentadienyl)-1,2-ethanediylzirconium dimethyl, (tert-butylamido)(tetramethyl-eta⁵-cyclopentadienyl)-1,2-ethanediyltitanium dimethyl, (methylamido)(tetramethyl-eta⁵-cyclopentadienyl)-1,2-ethanediylzirconium dibenzyl, (methylamido)(tetramethyl-eta⁵-cyclopentadienyl)-1,2-ethanediyltitanium dimethyl, (ethylamido)(tetramethyl-eta⁵-cyclopentadienyl)methylenetitanium dimethyl, (tertbutylamido)dibenzyl(tetramethyl-eta⁵-cyclopentadienyl)silanezirconium dibenzyl, (benzylamido)dimethyl-(tetramethyl-eta⁵ cyclopentadienyl)silanetitanium diphenyl, (phenylphosphido)dithyl(tetramethyl-O⁵-cyclopentadienyl)silanezirconium dibenzyl, and the like.

Such components are readily prepared by combining the corresponding metal chloride with a dilithium salt of the substituted cyclopentadienyl group such as a cyclopentadienyl-alanediyl, cyclopentadienyl-silane amide, or cyclopentadienyl-phosphide compound. The reaction is conducted in an inert liquid such as tetrahydrofuran, C₅₋₁₀ alkanes, toluene, etc. utilizing conventional synthetic procedures. Additionally, the first components may be prepared by reaction of a group II derivative of the cyclopentadienyl compound in a solvent and separating the salt by-product Magnesium derivatives of the cyclopentadienyl compounds are preferred. The reaction may be conducted in an inert solvent such as cyclohexane, pentane, tetrahydrofuran, diethyl ether, benzene, toluene, or mixtures of the like. The resulting metal cyclopentadienyl halide complexes may be alkylated using a variety of techniques. Generally, the metal cyclopentadienyl alkyl or aryl complexes may be prepared by alkylation of the metal cyclopentadienyl halide complexes with alkyl or aryl derivatives of group I or group II metals. Preferred alkylating agents are alkyl lithium and Grignard derivatives using conventional synthetic techniques. The reaction may be conducted in an inert solvent such as cyclohexane, pentane, tetrahydrofuran, diethyl ether, benzene, toluene, or mixtures of the like. A preferred solvent is a mixture of toluene and tetrahydrofuran.

Compounds useful as a second component in the preparation of the ionic catalysts useful in this invention will comprise a cation, which is a Bronsted acid capable of donating a proton, and a compatible noncoordinating anion. Preferred anions are those containing a single coordination complex comprising a charge-bearing metal or metalloid core which anion is relatively large (bulky), capable of stabilizing the active catalyst species (the Group 3-10 or Lanthanide Series cation) which is formed when the two components are combined and suffciently labile to be displaced by olefinic, diolefinic and acetylenically unsaturated substrates or other neutral Lewis bases such as ethers, nitriles and the like. Suitable metals, then, include, but are not limited to, aluminum, gold, platinum and the like. Suitable metatloids include, but are not limited to, boron, phosphorus, silicon and the like. Compounds containing anions which comprise coordination complexes containing a single metal or metalloid atom are, of course, well known and many, particularly such compounds containing a single boron atom in the anion portion, are available commercially. In light of this, salts containing anions comprising a coordination complex containing a single boron atom are preferred.

Highly preferably, the second component useful in the preparation of the catalysts of this invention may be represented by the following general formula:

(L—H)+[A]—

wherein:

L is a neutral Lewis base;

(L—H)+is a Bronsted acid; and

[A]— is a compatible, noncoordinating anion.

More preferably [A]— corresponds to the formula:

[M′Q_(q]—)

wherein:

M′ is a metal or metalloid selected from Groups 5-15 of the Periodic Table of the Elements; and

Q independently each occurrence is selected from the Group consisting of hydride, dialkylamido, halide, alkoxide, aryloxide, hydrocarbyl, and substituled-hydrocarbyl radicals of up to 20 carbons with the proviso that in not more than one occurrence is Q halide and

q is one more than the valence of M′.

Second components comprising boron which are particularly useful in the preparation of catalysts of this invention may be represented by the following general formula:

[L—H]+[BQ₄]—

wherein:

L is a neutral Lewis base;

[L—H]+ is a Bronsted acid;

B is boron in a valence state of 3; and

Q is as previously defined.

Illustrative, but not limiting, examples of boron compounds which may be used as a second component in the preparation of the improved catalysts of this invention are trialkyl-substituted ammonium salts such as triethylammonium tetraphenylborate, tripropylammonium tetraphenylborate, tris(n-butyl)ammonium tetraphenylborate, trimethylammonium tetrakis(p-tolyl)borate, tributylammonium tetrakis(pentafluorophenyl)borate, tripropylamnmonium tetrakis(2,4-dimethylphenyl)borate, tributylammonium tetrakis(3,5-dimethylphenyl)borate, triethylammonium tetrakis(3,5di-trifluoromethylphenyl)borate and the like. Also suitable are N,N-dialkyl anilinium salts such as N,N-dimethyl-aniliniumtetraphenylborate, N,N-diethylaniium tetraphenylborate, N,N-2,4,6-pentamethylanilinium tetraphenylborate and the like; diallylammonium salts such as di-(i-propyl)ammonium tetrakis(pentafluorophenyl)borate, dicyclohexylammonium tetraphenylborate and the like; and triaryl phosphonium salts such as triphenylphosphonium tetraphenylborale, tri(methylphenyl)phosphonium tetrakis-pentafluorophenylborate, tri(dimethylphenyl)phosphonium tetraphenylborate and the like.

Preferred ionic catalysts are those having a limiting charge separated structure corresponding to the formula:

wherein:

M is a metal of group 3-10, or the Lanthanide series of the Periodic Table of the Elements;

Cp* is a cyclopentadienyl or substituted cyclopentadienyl group bound in an eta⁵ bonding mode to M;

Z is a moiety comprising boron, or a member of group 14 of the Periodic Table of the Elements, and optionally sulfur or oxygen, said moiety having up to 20 non-hydrogen atoms, and optionally Cp* and Z together form a fused ring system;

X independently each occurrence is an anionic ligand group or neutral Lewis base ligand group having up to 30 non-hydrogen atoms;

n is 0, 1, 2, 3, or 4 and is 2 less than the valence of M; and

XA*— is —XB(C₆F₅)₃.

This class of cationic complexes may be conveniently prepared by contacting a metal compound corresponding to the formula;

wherein:

Cp*, M, and n are as previously defined, with tris(pentafluorophenyl)borane cocatalyst under conditions to cause abstraction of X and formation of the anion —XB(C₆F₅)₃.

Preferably X in the foregoing ionic catalyst is C₁-C₁₀ hydrocarbyl, most preferably methyl.

The preceding formula is referred to as the limiting, charge separated structure. However, it is to be understood that, particularly in solid form, the catalyst may not be fully charge separated. That is, the X group may retain a partial covalent bond to the metal atom, M. Thus, the catalysts may be alternately depicted as possessing the formula:

The catalysts are preferably prepared by contacting the derivative of a Group 4 or Lanthanide metal with the tris(pentafluorophenyl)borane in an inert diluent such as an organic liquid.

Tris(pentafluorphenyl)borane is a commonly available Lewis acid that may be readly prepared according to known techniques. The compound is disclosed in Marks, et al. J. Am. Chem. Soc. 1991, 113, 3623-3625 for use in alkyl abstraction of zirconocenes.

All reference to the Periodic Table of the Elements herein shall refer to the Periodic Table of the Elements, published and copyrighted by CRC Press, Inc., 1989. Also, any reference to a Group or Groups shall be to the Group or Groups as reflected in this Periodic Table of the Elements using the IUPAC system for numbering groups.

It is believed that in the constrained geometry catalysts used herein the metal atom is forced to greater exposure of the active metal site because one or more substituents on the single cyclopentadienyl or substituted metal is both bonded to an adjacent covalent moiety and held in association with the cyclopentadienyl group through an eta⁵ or other pi-bonding interaction. It is understood that each respective bond between the metal atom and the constituent atoms of the cyclopentadienyl or substituted cyclopentadienyl group need not be equivalent. That is, the metal may be symmetrically or unsymmetrically pi-bound to the cyclopentadienyl or substituted cyclopentadienyl group.

The geometry of the active metal site is further defined as follows. The centroid of the cyclopentadienyl or substituted cyclopentadienyl group may be defined as the average of the respective X, Y, and Z coordinates of the atomic centers forming the cyclopentadienyl or substituted cyclopentadienyl group. The angle, theta, formed at the metal center between the centroid of the cyclopentadienyl or substituted cyclopentadienyl group and each other ligand of the metal complex may be easily calculated by standard techniques of single crystal X-ray diffraction Each of these angles may increase or decrease depending on the molecular structure of the constrained geometry metal complex. Those complexes wherein one or more of the angles, theta, is less than in a similar, comparative complex differing only in the fact that the constrain inducing substituent is replaced by hydrogen, have constrained geometry for purposes of the present invention Preferably one or more of the above angles, theta, decrease by at least 5 percent, more preferably 7.5 percent, compared to the comparative complex. Highly preferably, the average value of all bond angles, theta, is also less than in the comparative complex.

Preferably, monocyclopentadienyl metal coordination complexes of group 4 or lanthanide metals according to the present invention have constrained geometry such that the smallest angle, theta, between the centroid of the Cp* group and the Y substituent, is less than 115 degrees, more preferably less than 110 degrees, most preferably less than 105 degrees, and especially less than 100 degrees.

Other compounds which are useful in the catalyst compositions of this invention, especially compounds containing other Group 4 or Lanthanide metals, will, of course, be apparent to those skilled in the art.

Polymerization

The improved melt elasticity and processibility of the substantially linear polymers according to the present invention result, it is believed, from their method of production. The polymers may be produced via a continuous (as opposed to a batch) controlled polymerization process using at least one reactor (e.g., as disclosed in WO 93/07187, WO 93/07188, and WO 93/07189, the disclosures of each of which is incorporated herein by reference), but can also be produced using multiple reactors (e.g., using a multiple reactor configuration as described in U.S. Pat. No. 3,914,342, the disclosure of which is incorporated herein by reference) at a polymerization temperature and pressure sufficient to produce the interpolymers having the desired properties.

While not wishing to be bound by any particular theory, the inventors believe that long chain branches are formed in their novel polymers according to the following sequence:

Propagation Step

R—(C₂H₄)+Catalyst→R—C₂H₄-Catalyst

Termination Step

R—C₂H₄-Catalyst→R—CH═CH₂ (beta-hydride elimination)

Copolymerization

R—CH₂—CH₂—CHR′—CH₂-Catalyst→R—CH₂—CH₂—CHR′—CH₂-Catalyst

Continued Polymerization

 R—CH₂—CH₂—CHR′—CH₂-Catalyst+(C₂H₄)_(x)→R—CHR′(CH₂CH₂)_(x)-Catalyst

Termination Step

1) R—CHR′(CH₂CH₂)_(x)-Catalyst+Heat→R—CHR′R″CH═CH₂+H-Catalyst

2) R—CHR′(CH₂CH₂)_(x)-Catalyst+H₂→R—CHR′R″+H-Catalyst

wherein:

R=growing polymer chain

R′=long chain branch (LCB), and

R″=growing polymer chain after insertion of R″.

In polymerizing ethylene and ethylene/alpha-olefin copolymers, a batch reactor process typically operates at an ethylene concentration from about 6.7 to about 12.5 percent by weight of the reactor contents and have a polymer concentration generally less than about 5 percent by weight of the reactor contents, dependent upon the ethylene solubility, which is a function of reactor diluent, temperature and pressure. Ile initital polymer concentration is zero and increases over time as the reaction proceeds such that the highest polymer concentration occurs at the end of the reaction, the point at which the catalyst is spent. Most of the polymer is made during the initial minutes of the polymerization.

According to one embodiment of the present process, the polymers are produced in a continuous process operated at a steady state (i.e. the reactants are fed to the reactor at a rate in substantially in balance with the rate that product is removed from the reactor such that the reaction mass in the reactor is relatively constant in volume and composition), as opposed to a batch process. Preferably, the polymerization temperature of the continuous process is from about 20 C. to about 250 C., using constrained geometry catalyst technology. If a narrow molecular weight distribution polymer (M_(w)/M_(n) of from about 1.5 to about 2.5) having a higher I₁₀/I₂ ratio (e.g. I₁₀/I₂ of 7 or more, preferably at least 8, especially at least 9 and as high as about 20 or more) is desired, the ethylene concentration in the reactor is preferably not more than about 8 percent by weight of the reactor contents, especially not more than about 6 percent by weight of the reactor contents, and most especially not more than about 4 percent by weight of the reactor contents, and as low as about 0.75 percent by weight of the reactor contents. Preferably, the polymerization is performed in a solution polymerization process. Generally, manipulation of I₁₀/I₂ while holding M_(w)/M_(n) relatively low for producing the novel polymers described herein is a function of reactor temperature and/or ethylene concentration. Surprisingly, reduced ethylene concentration and higher temperature generally produces higher I₁₀/I₂. Generally, as the percent of ethylene is converted into polymer, the ethylene concentration in the reactor decreases and the polymer concentration increases. For the novel substantially linear ethylene/alpha-olefin copolymers and substantially linear ethylene homopolymers claimed herein, the polymer concentration for a continuous solution polymerization process is preferably above about 5 weight percent of the reactor contents, especially above about 15 weight percent of the reactor contents, and as high as about 40 weight percent of the reactor contents. Typically greater than 70 percent, preferably greater than 80 percent and more preferably greater than 90 percent, of the ethylene is converted to polymer.

The substantially linear polymers of the present invention can be ethylene homopolymers, or they can be interpolymers of ethylene with at least one C₃-C₂₀ alpha-olefin and/or C₄-C₁₈, diolefins. The substantially linear polymers of the present invention can also be interpolymers of ethylene with at least one of the above C₃-C₂₀ alpha-olefins and/or diolefins in combination with other unsaturated monomers.

Monomers usefully copolymerized or interpolymerized with ethylene according to the present invention include, for example, ethylenically unsaturated monomers, conjugated or nonconjugated dienes, polyenes, etc. Preferred comonomers include the C₃-C₁₀ alpha-olefins especially propene, isobutylene, 1-butene, 1-hexene, 4-methyl-1-pentene, and 1-octene. Other preferred monomers include styrene, halo- or alkyl substituted styrenes, vinylbenzocyclobutene, 1,4-hexadiene, and naphthenics (e.g., cyclo-pentene, cyclo-hexene and cyclo-octene).

Other unsaturated monomers usefully copolymerized according to the present invention include, for example, ethylenically unsaturated monomers, conjugated or nonconjugated dienes, polyenes, etc. Preferred comonomers include the C₃-C₁₀ alpha-olefins especially propene, isobutylene, 1-butene, 1-hexene, 4methyl-1-pentene, and 1-octene. Other preferred comonomers include styrene, halo- or alkyl substituted styrenes, vinylbenzocyclobutene, 1,4-hexadiene, and naphthenics (e.g., cyclopentene, cyclohexene and cyclooctene).

The polymerization conditions for manufacturing the polymers of the present invention are generally those useful in the solution polymerization process, although the application of the present invention is not limited thereto. Slurry and gas phase polymerization processes are also believed to be useful, provided the proper catalysts and polymerization conditions are employed.

Multiple reactor polymerization processes are also useful in the present invention, such as those disclosed in U.S. Pat. No. 3,914,342. The multiple reactors can be operated in series or in parallel, with at least one constrained geometry catalyst employed in at least one of the reactors.

In general, the continuous polymerization according to the present invention may be accomplished at conditions well known in the prior art for Ziegler-Natta or Kaminsky-Sinn type polymerization reactions, that is, temperatures from 0 to 250 C. and pressures from atmospheric to 1000 atmospheres (100 MPa). Suspension, solution, slurry, gas phase or other process conditions may be employed if desired. A support may be employed, but preferably the catalysts are used in a homogeneous (i.e., soluble) manner. It will, of course, be appreciated that the active catalyst system form in situ if the catalyst and the cocatalyst components thereof are added directly to the polymerization process and a suitable solvent or diluent, including condensed monomer, is used in said polymerization process. It is, however, preferred to form the active catalyst in a separate step in a suitable solvent prior to adding the same to the polymerization mixture.

The polymerization conditions for manufacturing the polymers of the present invention are generally those useful in the solution polymerization process, although the application of the present invention is not limited thereto. Gas phase polymerization processes are also believed to be useful, provided the proper catalysts and polymerization conditions are employed.

Fabricated articles made from the novel ethylene polymers may be prepared using all of the conventional polyethylene processing techniques. Useful articles include films (e.g., cast, blown and extrusion coated), fibers (e.g., staple fibers (including use of a novel ethylene polymer disclosed herein as at least one component comprising at least a portion of the fiber's surface), spunbond fibers or melt blown fibers (using, e.g., systems as disclosed in U.S. Pat. Nos. 4,340,563, 4,663,220, 4,668,566, or 4,322,027), and gel spun fibers (e.g., the system disclosed in U.S. Pat. No. 4,413,110)), both woven and nonwoven fabrics (e.g., spunlaced fabrics disclosed in U.S. Pat. No. 3,485,706) or structures made from such fibers (including, e.g., blends of these fibers with other fibers, e.g., PET or cotton) and molded articles (e.g., made using an injection molding process, a blow molding process or a rotomolding process). The new polymers described herein are also useful for wire and cable coating operations, impact modification, especially at low temperatures, of thermoplastic olefins (e.g., polypropylene), as well as in sheet extrusion for vacuum forming operations, closed cell and open cell foams (including radiation and chemically crosslinked foams and foam structures), and adhesives. All of the preceding patents are incorporated herein by reference.

Useful compositions are also suitably prepared comprising the substantially linear polymers of the present invention and at least one other natural or synthetic polymer. Preferred other polymers include thermoplastics such as styrene-butadiene block copolymers, polystyrene (including high impact polystyrene), ethylene vinyl acetate copolymers, ethylene acrylic acid copolymers, other olefin copolymers (especially polyethylene copolymers) and homopolymers (e.g., those polyethylene copolymers and homopolymers made using conventional heterogeneous catalysts). Examples of such heterogeneous polyethylene polymers and copolymers include polymers made by the process of U.S. Pat. No. 4,076,698 (incorporated herein by reference), other linear or substantially linear polymers of the present invention, and mixtures thereof. Other substantially linear polymers of the present invention and conventional heterogeneously branched HDPE and/or heterogeneously branched LLDPE are preferred for use in the thermoplastic compositions.

The compositions comprising the substantially linear ethylene polymers are formed by any convenient method, including dry blending the individual components and subsequently melt mixing, either directly in the extruder used to make the finished article (e.g., film), or by pre-melt mixing in a separate extruder. The polyethylene compositions may also be prepared by multiple reactor polymerization techniques. For example, one reactor may polymerize the constrained geometry catalyzed polyethylene and another reactor polymerize the heterogeneous catalyzed polyethylene, either in series or in parallel operation.

Compositions comprising the ethylene polymers can also be formed into fabricated articles such as those previously mentioned using conventional polyethylene processing techniques which are well known to those skilled in the art of polyethylene processing.

For examples described herein, unless otherwise stipulated, all procedures were performed under an inert atmosphere of nitrogen or argon. Solvent choices were often optional, for example, in most cases either pentane or 30-60 petroleum ether can be interchanged. Amines, silanes, lithium reagents, and Grignard reagents were purchased from Aldrich Chemical Company. Published methods for preparing tetranethylcyclopentadiene (C₅Me₄H₂) and lithium tetramethylcyclopentadienide (Li(C₅Me₄H)) include C. M. Fendrick et al. Organometallcs, 3, 819 ( 1984). Lithiated substituted cyclopentadienyl compounds may be typically prepared from the corresponding cyclopentadiene and a lithium reagent such as n-butyl lithium. Titanium trichloride (TiCl₃) was purchased from Aldrich Chemical Company. The tetrahydrofuran adduct of titanium trichloride, TiCl₃(THF)₃, was prepared by refluxing TiCl₃ in THF overnight, cooling, and isolating the blue solid product, according to the procedure of L. E. Manzer, Inorg. Syn., 21, 135 (1982).

EXAMPLE 1-4

The metal complex solution for Example I is prepared as follows:

Part 1: Prep of Li(C₅Me₄H)

In the dryhox, a 3L 3-necked flask was charged with 18.34 g of C₅Me₄H₂, 800 mL of pentane, and 500 mL of ether. The flask was topped with a reflux condenser, a mechanical stirrer, and a constant addition funnel container 63 mL of 2.5 M n-BuLi in hexane. The BuLi was added dropwise over several hours. A very thick precipitate formed; approx. 1000 mL of additional pentane had to be added over the course of the reaction to allow stirring to continue. After the addition was complete, the mixture was stirred overnight. The next day, the material was filtered, and the solid was thoroughly washed with pentane and then dried under reduced pressure. 14.89 g of Li(C₅Me₄H) was obtained (78 percent).

Part 2: Prep of C₅Me₄HSiMe₂Cl

In the drybox 30.0 g of L(iC₅Me₄H) was placed in a 500 mL Schlenk flask with 250 mL of THF and a large magnetic stir bar. A syringe was charged with 30 mL of Me2SiCl₂ and the flask and syringe were removed from the drybox. On the Schlenk line under a flow of argon, the flask was cooled to −78 C., and the Me₂SiCl₂ added in one rapid addition. The reaction was allowed to slowly warm to room temperature and stirred overnight. The next morning the volatile materials were removed under reduced pressure, and the flask was taken into the drybox. The oily material was extracted with pentane, filtered, and the pentane was removed under reduced pressure to leave the C₅Me₄HSiMe₂Cl as a clear yellow liquid (46.83 g; 92.9 percent).

Part 3: Prep of C₅Me₄HSiMe₂NH^(t)Bu

In the drybox, a 3-necked 2 L flask was charged with 37.4 g of t-butylamine and 210 mL of THF. C₅Me₄HSiMe₂Cl (25.47 g) was slowly dripped into the solution over 3-4 hours. The solution turned cloudy and yellow. PTe mixture was stirred overnight and the volatile materials removed under reduced pressure. The residue was extracted with diethyl ether, the solution was filtered, and the ether removed under reduced pressure to leave the C₅Me₄HSiMe₂NH^(t)Bu as a clear yellow liquid (26.96 g; 90.8 percent).

Part 4: Prep of [MgCl]₂[Me₄C₅SiMe₂N^(t)Bu](THF)_(x)

In the drybox, 14.0 mL of 2.0 M isopropylmagnesium chloride in ether was syringed into a 250 mL flasks The ether was removed under reduced pressure to leave a colorless oil. 50 mL of a 4:1 (by volume) toluene:THF mixture was added followed by 3.50 g of Me₄HC₅SiMe₂NH^(t)Bu. The solution was heated to reflux. After refluxing for 2 days, the solution was cooled and the volatile materials removed under reduced pressure. The white solid residue was slurried in pentane and filtered to leave a white powder, which was washed with pentane and dried under reduced pressure. The white powder was identified as [MgCl]₂[Me₄C₅SiMe₂N^(t)Bu](THF)_(x) (yield: 6.7 g).

Part 5: Prep of [C₅Me₄(SiMe₂N^(t)Bu)]TiCl₂

In the drybox, 0.50 g of TiCl₃(THF)₃ was suspended in 10 mL of THF. 0.69 g of solid [MgCl]₂[Me₄C₅SiMe₂N^(t)Bu](THF)_(x) was added, resulting in a color change from pale blue to purple. After 15 minutes, 0.35 g of AgCl was added to the solution. The color immediately began to lighten to a pale green/yellow. After 1.5 hours, the THF was removed under reduced pressure to leave a yellow-green solid. Toluene (20 mL) was added, the solution was filtered, and the toluene was removed under reduced pressure to leave a yellow-green solid, 0.51 g (quantitative yield) identified by 1H NMR as [C₅Me₄(SiMe₂N^(t)Bu)]TiCl₂.

Part 6: Preparation of [C₅Me₄(SiMe₂N^(t)Bu)]TiMe₂

In an inert atmosphere glove box, 9.031 g of [C₅Me₄(Me₂SiN^(t)Bu)]TiCl₂ is charged into a 250 ml flask and dissolved into 100 ml of THF. This solution is cooled to about −25 C. by placement in the glove box freezer for 15 minutes. To the cooled solution is added 35 ml of a 1.4 M MeMgBr solution in toluene/THF (75/25). The reaction mixture is stirred for 20 to 25 minutes followed by removal of the solvent under vacuum. The resulting solid is dried under vacuum for several hours. The product is extracted with pentane (4×50 ml) and filtered. The filtrate is combined and the pentane removed under vacuum giving the catalyst as a straw yellow solid.

The metal complex, [C₅Me₄(SiMe₂N^(t)Bu)]TiMe₂, solution for Examples 2 and 3 is prepared as follows:

In an inert atmosphere glove box 10.6769 g of a tetrahydrofuran adduct of titanium trichloride, TiCl₃(THF)₃, is loaded into a 1 L flask and slurried into 300 ml of THF. To this slurry, at room temperature, is added 17.402 g of [MgCl]₂ [N^(t)BuSiMe₂C₅Me₄] (THF)_(x) as a solid. An additional 200 ml of THF is used to help wash this solid into the reaction flask. This addition resulted in an immediate reaction giving a deep purple solution. After stirring for 5 minutes 9.23 ml of a 1.56 M solution of CH₂C₂ in THF is added giving a quick color change to dark yellow. This stage of the reaction is allowed to stir for about 20 to 30 minutes. Next, 61.8 ml of a 1.4 M MeMgBr solution in toluene/THF(75/25) is added via syringe. After about 20 to 30 minutes stirring time the solvent is removed under vacuum and the solid dried. The product is extracted with pentane (8×50 ml) and filtered. The filtrate is combined and the pentane removed under vacuum giving the metal complex as a tan solid.

The metal complex, [C₅Me₄(SiMe₂N^(t)Bu)]TiMe₂, solution for Example 4 is prepared as follows:

In an inert atmosphere glove box 4.8108 g of TiCl₃(THF)₃ is placed in a 500 ml flask and slurried into 130 ml of THF. In a separate flask 8.000 g of [MgCl]₂[N^(t)BuSiMe₂C₅Me₄](THF)_(x) is dissolved into 150 ml of THF. These flasks are removed from the glove box and attached to a vacuum line and the contents cooled to −30 C. The THF solution of [MgCl]₂[N^(t)BuSiMe₂C₅Me₄](THF)_(x) is transferred (over a 15 minute period) via cannula to the flask containing the TiCl₃(THF)₃ slurry. This reaction is allowed to stir for 1.5 hours over which time the temperature warmed to 0 C. and the solution color turned deep purple. The reaction mixture is cooled back to −30 C. and 4.16 ml of a 1.56 M CH₂Cl₂ solution in THF is added. This stage of the reaction is stirred for an additional 1.5 hours and the temperature warmed to −10 C. Next, the reaction mixture is again cooled to −40 C. and 27.81 ml of a 1.4 M MeMgBr solution in toluene/THF (75/25) was added via syringe and the reaction is now allowed to warm slowly to room temperature over 3 hours. After this time the solvent is removed under vacuum and the solid dried. At this point the reaction flask is brought back into the glove box where the product is extracted with pentane (4×50 ml) and filtered. The filtrate is combined and the pentane removed under vacuum giving the catalyst as a tan solid. The metal complex is then dissolved into a mixture of C₈-C₁₀ saturated hydrocarbons (e.g., Isopar™ E, made by Exxon) and ready for use in polymerization.

Polymerization

The polymer products of Examples 1-4 are produced in a solution polymerization process using a continuously stirred reactor. Additives (e.g., antioxidants, pigments, etc.) can be incorporated into the interpolymer products either during the pelletization step or after manufacture, with a subsequent re-extrusion. Examples 1-4 are each stabilized with 1250 ppm calcium stearate, 200 ppm Irganox 1010, and 1600 ppm Irgafos 168. Irgafos™ 168 is a phosphite stabilizer and Irganox™ 1010 is a hindered polyphenol stabilizer (e.g., tetmids [methylene 3-(3,5-ditertbutylhydroxyphenylpropionate)]methane. Both are trademarks of and made by Ciba-Geigy Corporation. A representative schematic for the polymerization process is shown in FIG. 1.

The ethylene (4) and the hydrogen are combined into one stream (15) before being introduced into the diluent mixture (3). Typically, the diluent mixture comprises a mixture of C₈-C₁₀ saturated hydrocarbons (1), (e.g., Isopar™E, made by Exxon) and the comonomer(s) (2). For Example 1, the comonomer is 1-octene. The reactor feed mixture (6) is continuously injected into the reactor (9). The metal complex (7) and the cocatalyst (8) (the cocatalyst is tris(pentafluorophenyl)borane for Examples 1-4 herein which forms the ionic catalyst in situ) are combined into a single stream and also continuously injected into the reactor. Sufficient residence time is allowed for the metal complex and cocatalyst to react to the desired extent for use in the polymerization reactions, at least about 10 seconds. For the polymerization reactions of Examples 1-4, the reactor pressure is held constant at about 490 psig. Ethylene content of the reactor, after reaching steady state, is maintained below about 8 percent.

After polymerization, the reactor exit stream (14) is introduced into a separator (10) where the molten polymer is separated from the unreacted comonomer(s), unreacted ethylene, unreacted hydrogen, and diluent mixture stream (13). The molten polymer is subsequently strand chopped or pelletized and, after being cooled in a water bath or pelletizer ( 1), the solid pellets are collected (12). Table I describes the polymerization conditions and the resultant polymer properties:

TABLE I Example 1* 2 3 4 Ethylene feed rate (lbs/hour) 3.2 3.8 3.8 3.8 Comonomer/Total Olefin ratio* (mole percent) 12.3 0 0 0 Hydrogen/ethylene ratio (mole percent) 0.054 0.072 0.083 0.019 Diluent/ethylene ratio (weight basis) 9.5 7.4 8.7 8.7 Metal complex conc. 0.00025 0.0005 0.001 0.001 (molar) Metal complex flow rate (ml/min) 5.9 1.7 2.4 4.8 Cocatalyst conc. 0.001 0.001 0.002 0.002 (molar) Cocatalyst flow rate (ml/min) 2.9 1.3 6 11.9 Reactor temp (EC) 114 160 160 200 Polymer conceNtration (wt %) in the reactor exit 7.1 8.4 9.5 8.4 stream Comonomer concentration (wt %) in the reactor exit 3.8 0 0 0 stream Ethylene conc. in the reactor exit stream 2.65 3.59 0.86 1.98 (weight percent) Product I₂ 1.22 0.96 1.18 0.25 (g/10 minutes) Product density 0.903 0.954 0.954 0.953 (g/cm³) Product I₁₀/I₂ 6.5 7.4 11.8 16.1 Single DSC Melting Peak (C) 97 132 131 132 Product M_(w) 95,400 93,800 71,600 105,800 Product M_(n) 50,000 48,200 34,200 51,100 Product M_(W)/M_(s) 1.91 1.95 2.09 2.07 Ethylene Conversion (%) 71 70 92 81 LCB/Chain N.M.** — 0.53 0.66 LCB/10,000 Carbons N.M.** — 2.2 1.8 Aluminium Residue (ppm) 0 0 0 0

*For Example 1, the Comonomer/Total Olefin ratio is defined as the percentage molar ratio of 1-octene/(1-octene+ethylene). Ex. 1* is a Comparative Example since the copolymer has onset of gross melt fracture less than 4×10⁶ dyne/cm². **N.M.=Not Measured.

The ¹³C NMR spectrum of Example 3 (ethylene homopolymer) shows peaks which can be assigned to the alpha,delta⁺, beta,delta⁺and methine carbons associated with a long chain branch. Long chain branching is determined using the method of Randall described earlier in this disclosure, wherein he states that “Detection of these resonances in high-density polyethylenes where no 1-olefins were added during the polymerization should be strongly indicative of the presence of long chain branching.” Using the equation 141 from Randall (p. 292):

Branches per 10,000 carbons=[1/3(alpha)/T _(Tα)]×10⁴,

wherein alpha=the average intensity of a carbon from a branch (alpha,delta⁺) carbon and T_(Tα)=the total carbon intensity. The number of long chain branches in this sample is determined to be 3.4 per 10,000 total carbon atoms, or 0.34 long chain branches/1000 total carbon atoms using 300 MHz ¹³C NMR, and 2.2 per 10,000 total carbon atoms, or 0.22 long chain branches/1000 total carbon atoms using a 600 MHz ¹³C. NMR.

EXAMPLE 5, 6 Comparative Examples 7-9

Examples 5, 6 and Comparison Examples 7-9 with the same melt index are tested for rheology Comparison. Examples 5 and 6 are the substantially linear ethylene/1-octene copolymers produced by the constrained geometry catalyst technology, as described in Example 1, with the exception that lower ethylene concentrations were used for Examples 5 and 6 providing for higher I₁₀/I₂ ratios and consequently more long chain branching than Example 1. Examples 5 and 6 are stabilized as Examples 1-4. Comparison Examples 7, 8 and 9 are conventional heterogeneous Ziegler polymerization blown film resins Dowlex™ 2045A, Attane™ 4201, and Attane™ 4403, respectively, all of which are ethylene/1-octene copolymers made by The Dow Chemical Company.

Comparative Example 7 is stablized with 200 ppm Irganox™ 1010, and 1600 ppm Irgafos™ 168 while Comparative Examples 8 and 9 are stablized with 200 ppm Irganox™ 1010 and 800 ppm PEPQ™. PEPQ™ is a trademark of Sandoz Chemical, the primary ingredient of which is believed to be tetrak-(2,4di-tertbutyl-phenyl)4,4′ biphenylphosphonite. A comparison of the physical properties of each Example and Comparative Example is listed in Table II.

TABLE II Comparative Comparative Comparative Property Ex. 5 Ex. 6 Example 7 Example 8 Example 9 I₂ 1 1 1 1 0.76 (g/10 minutes) Density 0.92 0.902 0.92 0.912 0.905 (g/cm³) I₁₀/I₂ 9.45 7.61 7.8-8 8.2 8.7 Product M_(w) 73,800 96,900 124,600 122,500 135,300 Product M_(n) 37,400 46,400 34,300 32,500 31,900 Product M_(w)/M_(n) 1.97 2.09 3.5-3.8 3.8 3.8-4.2 DSC Melt 111 95 114, 118, 122 100, 116, 121 96, 116, 121 Peak(s) (C)

Surprisingly, even though the molecular weight distribution of Examples 5 and 6 is narrow (i.e., M_(w)/M_(n) is low), the I₁₀/I₂ values are comparable or higher in comparison with Comparative Examples 7-9. A comparison of the relationship between I₁₀/I₂vs. M_(w)/M_(n) for 2some of the novel polymers described herein and conventional heterogeneous Ziegler polymers is given in FIG. 2. The I₁₀/I₂ value for the novel polymers of the present invention is essentially independent of the molecular weight distribution, M_(w)/M_(n) which is not true for conventional Zieler polymerized resins.

Example 5 and Comparative Example 7 with similar melt index and density (Table II) are also extruded via a Gas Extrusion Rheometer (GER) al 190 C. using a 0.0296″ diameter, 20:1 L/D die. The processing index (P.I.) is measured at an apparent shear stress of 2.15×10⁶ dyne/cm² as described previously. The onset of gross melt fracture can easily be identified from the shear stress vs. shear rate plot shown in FIG. 3 where a sudden jump of shear rate occurs. A comparison of the shear stresses and corresponding shear rates before the onset of gross melt fracture is listed in Table III. It is particularly interesting that the PI of Example 5 is more than 20 percent lower than the PI of Comparative Example 7 and that the onset of melt fracture or sharkskin for Example 5 is also at a significantly higher shear stress and shear rate in comparison with the Comparative Example 7. Furthermore, the Melt Tension (MT) as well as Elastic Modulus of Example 5 are higher than that of Comparative Example 7.

Note that each of the Comparative Examples 7-9 has three distinct melting peaks as measured by DSC, which is evidence of their heterogeneous branching distribution. In contrast, the polymers of Examples 5 and 6 have a single melting peak as measured by DSC between the temperatures of −30 and 150 C. which is evidence of the homogeneity of the polymers branching distribution. Furthermore, the single melting peaks of Examples 5 and 6 indicate that each polymer is not a “blend” unlike the polymers disclosed in U.S. Pat. No. 5,218,071.

TABLE III Comparative Property Example 5 Example 7 I₂ 1 1 (g/10 minutes) I₁₀/I₂ 9.45 7.8-8 PI (kpoise) 11 15 Melt tension (gms) 1.89 1.21 Elastic modulus at 0.1 2425 882.6 rad/sec (dynes/cm²) OGMF*, critical shear rate >1556 936 (1/sec) (not observed) OGMF*, critical shear stress ≧0.452 0.366 (MPa) (not observed) OMF**, critical shear rate >1566 about 628 (1/sec) (not observed) OSMF**, critical shear stress ≧0.452 about 0.25 (MPa) (not observed) *Onset of Gross Melt Fracture. **Onset of Surface Melt Fracture.

Example 6 and Comparison Example 9 have similar melt index and density, but Example 6 has lower I₁₀/I₂ (Table IV). These polymers are extruded via a Gas Extrusion Rheometer (GER) at 190 C. using a 0.0296 inch diameter, 20:1 L/D die. The processing index (PI) is measured at an apparent shear stress of 2.15×10⁶ dyne/cm² as described previously.

TABLE IV Comparative Property Example 6 Example 9 I₂ 1 0.76 (g/10 minutes) I₁₀/I₂ 7.61 8.7 PI (kpoise) 14 15 Melt tension (gms) 1.46 1.39 Elastic modulus at 0.1 1481 1921 rad/sec (dynes/cm²) OGMF*, critical shear rate 1186 652 (1/sec) OGMF*, critical shear stress 0.431 0.323 (MPa) OSMF**, critical shear rate about 764 about 402 (1/sec) OSMF**, critical shear stress 0.366 0.280 (MPa) *Onset of Gross Melt Fracture. **Onset of Surface Melt Fracture.

The onset of gross melt fracture can easily be identified from the shear stress vs. shear rate plot shown in FIG. 4 where a sudden increase of shear rate occurs at an apparent shear stress of about 3.23×10⁶ dyne/cm² (0.323 MPa). A comparison of the critical shear stresses and corresponding critical shear rates at the onset of gross melt fracture is listed in Table IV. The PI of Example 6 is surprisingly about the same as Comparative Example 9, even though the I₁₀/I₂ is lower for Example 6. The onset of melt fracture or sharkskin for Example 6 is also at a significantly higher shear stress and shear rate in comparison with the Comparative Example 9. Furthermore, it is also unexpected that the Melt Tension (MT) of Example 6 is higher than that of Comparative Example 9, even though the melt index for Example 6 is slightly higher and the I₁₀/I₂ is slightly lower than that of Comparative Example 9.

Comparative Examples 10-19

Batch ethylene/1-octene polymerizations were conducted under the following conditions:

Preparation of [HNEt₃]+[MeB(C₆F₅)₃]—

A 100 ml flask was charged with 1.00 gram of tris(pentafluorophenyl)boron (1.95 mmoi) and 70 ml of anhydrous pentane. After dissolution, 1.5 ml of MeLi (1.4 M in diethyl ether, 2.1 mmol, 1.07 equiv) was added at 25 C. via syringe. A milky white mixture formed immediately and, after several minutes, two phases formed. The mixture was stirred for 15 hr and then the upper layer decanted. The viscous lower layer was washed twice with 30 ml of pentane and concentrated in vacuo for 2 hours to give a clear, colorless, viscous oil. Under nitrogen, the oil was quenched with a 40 ml of an aqueous 0.5 M HNEt₃Cl solution (20 mmol, 10 equiv) which had previously been cooled to 0 C. A white, gooey precipitate formed instantly. After two minutes, the solid was collected by filtration and washed twice with 20 ml of 0.5 M HNEt₃Cl solution followed by two washings with distilled water. The solid was dehydrated under high vacuum at 25 C. for 15 hours to give a powdery white solid (0.77 grams, 63%) which was identified as the desired triethylammonium tris(pentafluorophenyl)methylborate salt.

Preparation of [HNEt₃]+[(allyl)B(C₆F₅)₃]—

A 100 ml flask was charged with 1.00 gram of tris(pentafluorophenyl)boron (1.95 mmol) and 40 ml of anhydrous pentane. After dissolution, 2.05 ml of (allyl)MgBr (1.0 M in diethyl ether, 2.05 mmol, 1.05 equiv) was added at 25 C. via syringe. A cloudy white mixture formed immediately and, after several minutes, two phases formed. The mixture was stirred for 15 hr and then the upper layer decanted. The viscous lower layer was washed twice with 30 ml of pentane and concentrated in vacuo for 2 hours to give a clear, colorless, viscous oil. Under nitrogen, the oil was quenched with a 40 ml of an aqueous 0.5 M HNEt₃Cl solution (20 mmol, 10 equiv) which had previously been cooled to 0 C. A gooey, white precipitate formed after several minutes. The solid was collected by filtration and washed twice with 20 ml of 0.5 M HNEt₃Cl solution followed by two washings with distilled water. The solid was dehydrated under high vacuum at 25 C. for 15 hours to give a pasty white solid (0.39 grams, 30%) which was identified as the desired triethylammonium tris(pentafluorophenyl)allylborate salt Batch Reactor Polymerization Procedure

A 2 L stirred autoclave was charged with the desired amounts of a mixed alkane solvent (Isopar® E, available from Exxon Chemicals, Inc.) and 1-octene comonomer. The reactor was heated to the polymerization temperature. Hydrogen was added by differential pressure expansion from a 75 ml addition tank.

The term “hydrogen delta psi” in Table I represents the difference in pressure between the starting and final pressure in the hydrogen addition tank after adding hydrogen to the 2L reactor containing a total of approximately 1200 ml of solvent and 1-octene. The reactor was heated to the polymerization temperature and was saturated with ethylene to the desired pressure. For these experiments, a constant ethylene/solvent pressure of about 500 psig at a temperature of 140 C. corresponds to an ethylene concentration of about 8.4 percent by weight of the reactor contents. Metal complex and cocatalyst were mixed in a drybox by syringing the desired amount of 0.0050 M metal complex solution (in Isopar® E or toluene) into a solution of the cocatalyst (in Isopar® E or toluene). This solution was then transferred to a catalyst addition tank and injected into the reactor. The polymerization was allowed to proceed for the desired time and then the solution was drained from the bottom of the reactor and quenched with isopropanol About 100 mg of a hindered phenolic antioxidant (Irganox® 1010, available from Ciba-Geigy corporation) was added and the polymer was air dried overnight. The residual solvent was removed in a vacuum oven overnight. The results are shown in Table V and VA:

TABLE V 1- Comp H₂ octene Isopar yield Effcny. Aluminum Ex. (psi) (gms) E (gms) (gms) (gm/gm Ti) (ppm) 10A* 50 38 820 39.6 330,689 0 11A* 25 38 820 70.1 390,257 0 12A* 35 38 820 46.4 258,316 0 13A* 30 38 820 48.8 271,677 0 14A* 35 30 828 52.1 290,049 0 15A* 27 38 820 36.5 152,401 0 16A** 26 38 820 47.8 266,110 0 17B*** 35 40 818 19.7 41,127 6850 18B*** 50 40 818 19.7 41,127 6850 19B*** 25 40 818 18.3 38,204 7380 A = metal complex of [(C₅Me₄)SiMe₂N(t-Bu)] TiMe₂ (as in USP 5,064,802) B = metal complex of [(C₅Me₄)SiMe₂N(t-Bu))9 TiCl₂ (as in USP 5,026,798) * = Cocatalyst of [Et₃NH] + [(allyl)B(C₆F₅)₃]-(as in USP ‘802) ** = Cocatalyst of [Et₃NH] + [(Me)B(C₆F₅)₃]-(as in USP ‘802) *** = methyl aluminoxane (MAO) (as in USP ‘798) Reactor temperature is constant at about 140° C. Ethylene/solvent pressure is constant at about 500 psig Run time is about 15 minutes

TABLE VA Comp. μmoles μmoles Irganox 1010 Ex. complex cocatalyst (ppm) 10A* 2.5 2.5 2500 11A* 3.75 3.75 1400 12A* 3.75 3.75 2200 13A* 3.75 3.75 2000 14A* 3.75 3.75 1900 15A* 5 5 2700 16A* 3.75 3.75 2000 17B*** 10 5000 5000 18B*** 10 5000 5000 19B*** 10 5000 5500 A = metal complex of [(C₅Me₄)SiMe₂N(t-Bu)] TiMe₂ (as in USP 5,064,802) B = metal complex of [(C₅Me₄)SiMe₂N(t-Bu)] TiCl₂ (as in USP 5,026,798) * = Cocatalyst of [Et₃NH] + [(allyl)B(C₆F₅)₃]-(as in USP ‘802) ** = Cocatalyst of [Et₃NH] + [(Me)B(C₆F₅)₃]-(as in USP ‘802) *** = methyl aluminoxane (MAO) (as in USP ‘798) Reactor temperature is constant at about 140 C Ethylene/solvent pressure is constant at about 500 psig Run time is about 15 minutes

The samples were each extruded via a Gas Extrusion Rheometer (GER) at 190 C. using 0.0296 inch diameter die (preferably 0.0143 inch diameter die for high flow polymers, e.g. 50-100 MI or greater) having L/D of 20:1 and entrance angle of 180 degrees, as shown in the attached drawing. The OGMF can easily be identified from the shear stress vs. shear rate plot where a sudden jump of shear rate occurs or when the surface of the extrudate becomes very rough or irregular, or from deep ridges which can be clearly detected by visual observation. OSMF is characterized by fine scale surface irregularities ranging from loss of surface gloss to the more severe form of matte or sharkskin which can easily be seen using microscopy at a magnification of 40×.

Table VI displays the test results from Comparative Examples 10-19:

TABLE VI OGMF* OGMF* I₂ Shear Shear Comp. (gm/ Measured Rate Stress Ex. 10 min) I₁₀/I₂ (I₁₀/I₂) − 4.63 M_(w)/M_(n) (sec⁻¹) (MPa) 10 4.52 5.62 0.99 1.856 706 0.344 11 0.67 6.39 1.76 1.834 118 0.323 12 2.24 5.62 0.99 1.829 300 0.323 13 2.86 5.60 0.97 1.722 397 0.323 14 3.25 5.66 1.03 1.827 445 0.302 15 1.31 5.67 1.04 1.718 227 0.302 16 1.97 5.7 1.07 1.763 275 0.302 17 0.36 12.98 8.35 5.934 <29 .086 18 0.40 13.34 8.71 5.148 <11.08 <0.086 19 0.13 13.25 8.62 6.824 <10.39 <0.086

Comparative Examples 10-16 were prepared using the catalyst composition as described in U.S. Pat. No. 5,064,802 (Stevens et al.) as described above. Comparative Examples 17-19 were prepared using the catalyst composition described in U.S. Pat. No. 5,026,798 (Canich), as described above. All of the Comparative Polymer Examples made using a batch reactor at an ethylene concentration of about 8.4 percent by weight of the reactor contents or more tested had onset of gross melt fracture at a shear stress of less than or equal to 0.344 MPa (3.44×10⁶ dyne/cm²).

Interestingly, an ethylene concentration of about 8.4 percent is considered to be on the low side for a batch polymerization procedure, since it limits the reaction kinetics and slows the polymerization process. Increasing the ethylene concentration in a batch reactor, as is taught in U.S. Pat. No. 5,026,798 (Canich), where the calculated propylene reactor concentrations for these ten examples ranges from a low of about 12.6 percent (Example 1) to a high of about 79 percent (Example 6), by weight of the reactor contents, results in polymerization of polymers which do not have the novel structure discovered by Applicants, as the OGMF data in Table VI demonstrates. Furthermore, the I₁₀/I₂ ratio of such comparative polymers made using a batch reactor at relatively high ethylene concentrations increases as the molecular weight distribution, M_(w)/M_(n). increases, as is expected based on conventional Ziegler polymerized polymers.

EXAMPLE 20 Comparative Example 21

Blown film is fabricated from the two novel ethylene/1-octene polymers of Examples 5 and 6 made in accordance with the present invention and from two comparative conventional polymers made according to conventional Ziegler catalysis. The blown films are tested for physical properties, including heat seal strength versus heat seal temperature (shown in FIG. 5 for Examples 20 and 22 and Comparative Examples 21 and 23), machine (MD) and cross direction (CD) properties (e.g., tensile yield and break, elongation at break and Young's modulus). Other film properties such as dart, puncture, tear, clarity, haze, 20 degree gloss and block are also tested.

Blown Film Fabrication Conditions

The improved processing substantially linear polymers of the present invention produced via the procedure described earlier, as well as two comparative resins are fabricated on an Egan blown film line using the following fabrication conditions:

2 inch (5 cm) diameter extruder

3 inch (7.6 cm) die

30 mil die gap

25 RPM extruder speed

460 F. (238 C) melt temperature

1 mil gauge

2.7:1 Blow up ratio (12.5 inches (31.7 cm) layflat)

12.5 inches (31.7 cm) frost line height

The melt temperature is kept constant by changing the extruder temperature profile. Frost line height is maintained at 12.5 inches (31.7 cm) by adjusting the cooling air flow. The extruder output rate, back pressure and power consumption in amps are monitored throughout the experiment The polymers of the present invention and the comparative polymers are all ethylene/1-octene copolymers. Table VII summarizes physical properties of the two polymers of the invention and for the two comparative polymers:

TABLE VII Comparative Comparative Property Example 20 Example 21 Example 22 Example 23 I₂ (g/10 1 1 1 0.8 minutes) Density 0.92 0.92 0.902 0.905 (g/cm³) I₁₀/I₂ 9.45 about 8 7.61 8.7 M_(w)/M_(n) 1.97 about 4 2.09 about 5

Tables VIII and IX summarize the film properties measured for blown film made from two of these four polymers:

TABLE VIII Blown film properties Example Example Comparative Comparative Property 20 MD 20 CD Example 21 MD Example 21 CD Tensile 1391 1340 1509 1593 yield (psi) Tensile 7194 5861 6698 6854 break (psi) Elongation 650 668 631 723 (percent) Young's 18,990 19,997 23,086 23,524 modulus (psi) PPT* tear 5.9 6.8 6.4 6.5 (gms) *Puncture Propagation Tear MD = machine direction CD = cross direction

TABLE IX Example Comparative Property 20 Example 21 Dart A (grams) 472 454 Puncture (grams) 235 275 Clarity (percent transmittance) 71 68 Haze (percent) 3.1 6.4 20 degree gloss 114 81 Block (grams) 148 134

During the blown film fabrication, it is noticed that at the same screw speed (25 rpm) and at the same temperature profile, the extruder back pressure is about 3500 psi at about 58 amps power consumption for Comparative Example 21 and about 2550 psi at about 48 amps power consumption for Example 20, thus showing the novel polymer of Example 20 to have improved processability over that of a conventional heterogeneous Ziegler polymerized polymer. The throughput is also higher for Example 20 than for Comparative Example 21 at the same screw speed. Thus, Example 20 has higher pumping efficiency than Comparative Example 21 (i.e., more polymer goes through per turn of the screw).

As FIG. 5 shows, the heat seal properties of polymers of the present invention are improved, as evidenced by lower heat seal initiation temperatures and higher heat seal strengths at a given temperature, as compared with conventional heterogeneous polymers at about the same melt index and density.

EXAMPLE 24 and 25

The polymer products of Examples 24 and 25 are produced in a continuous solution polymerization process using a continuously stirred reactor, as described in copending U.S. Pat. No. 5, 272,236. The metal complex [C₅Me₄(SiMe₂N^(t)Bu)]TiMe₂ is prepared as described in U.S. Pat. No. 5,272,236 and the cocatalysts used are tris(pentafluorophenyl) borane (B:Ti ratio of 2:1) and MMAO (Al:Ti ratio of 4:1). For Example 24 the ethylene concentration in the reactor is about 1.10 percent and for Example 25 the ethylene concentration in the reactor is about 1.02 percent (percentages based on the weight of the reactor contents). For each Example, the reactor is run without hydrogen.

Additives (e.g., antioxidants, pigments, etc.) can be incorporated into the interpolymer products either during the pelletization step or after manufacture, with a subsequent re-extrusion. Examples 24 and 25 are each stabilized with 1250 ppm Calcium Stearate, 200 ppm Irganox 1010, and 1600 ppm Irgafos 168. Irgafos™ 168 is a phosphite stabilizer and Irganox™ 1010 is a hindered polyphenol stabilizer (e.g., tetrakis [methylene3-(3,5-ditertbutyl4-hydroxyphenylpropionate)]methane. Both are trademarks of and made by Ciba-Geigy Corporation.

EXAMPLE 24 Comparative Example 26

Example 24 is an ethylene/1-octene elastic substantially linear ethylene polymer produced as described herein.

Comparative Example 26 is an ethylene/1-butene copolymer trademarked Exact™ made by Exxon Chemical containing butylated hydroxy toluene (BHT) and Irganox™ 1076 as polymeric stabilizers. Table X summarizes physical properties and rheological performance of Example 24 and Comparative Exanple 26:

TABLE X Comparative Property Example 24 Example 26 I₂ (g/10 minutes) 3.3 3.58 Density (g/cm³) 0.870 0.878 I₁₀/I₂ 7.61 5.8 M_(w)/M_(n) 1.97 1.95 PI (kPoise) 3.2 8.4 Elastic Modulus @ 0.1 rad/sec 87.7 8.3 (dyne/cm²) OSMF*, critical shear rate 660 250 (sec⁻¹) *Onset of surface melt fracture

Even though Example 24 and Comparative Example 26 have very similar molecular weight distributions (M_(w)/M_(n)), I₂ and density, Example 24 has a much lower processing index (PI) (38 percent of the PI of Comparative Example 26), a much higher shear rate at the onset of surface melt fracture (264 percent of shear rate at onset of OSMF) and an elastic modulus an order of magnitude higher than Comparative Example 26, demonstrating that Example 24 has much better processability and higher melt elasticity than Comparative Example 26.

Elastic modulus is indicative of a polymer's melt stability, e.g., more stable bubbles when making blown film and lees neck-in during melt extrusion. Resultant physical properties of the finished film are also higher.

Onset of surface melt fracture is easily identified by visually observing the surface extrudate and noting when the extrudate starts losing gloss and small surface roughness is detected by using 40×magnification.

Dynamic shear viscosity of the polymers is also used to show differences between the polymers and measures viscosity change versus shear rate. A Rheometrics Mechanical Spectrometer (Model RMS 800) is used to measure viscosity as a function of shear rate. The RMS 800 is used at 190 C. at 15 percent strain and a frequency sweep (i.e., from 0.1-100 rad/sec) under a nitrogen purge. The parallel plates are positioned such that they have a gap of about 1.5-2 mm. Data for Example 24 and Comparative Example 26 are listed in Table XI and graphically displayed in FIG. 6.

TABLE XI Dynamic Viscosity Shear Rate Dynamic Viscosity (poise) (poise) for Comparative (rad/sec) for Example 24 Example 26 0.1 28290 18990 0.1585 28070 18870 0.2512 27630 18950 0.3981 27140 18870 0.631 26450 18840 1 25560 18800 1.585 24440 18690 2.512 23140 18540 3.981 21700 18310 6.31 20170 17960 10 18530 17440 15.85 16790 16660 25.12 14960 15620 39.81 13070 14310 63.1 11180 12750 100 9280 10960

Surprisingly, Example 24 shows a shear thinning behaviour, even though Example 24 has a narrow molecular weight distribution In contrast, Comparative Example 26 shows the expected behaviour of a narrow molecular weight distribution polymer, with a flatter viscosity/shear rate curve.

Thus, elastic substantially linear ethylene polymers made in accordance with the present invention (e.g. Example 24) have lower melt viscosity than a typical narrow molecular weight distribution linear copolymer made by single site catalyst technology at the melt processing shear rate region of commercial interest In addition, the novel elastic substantially linear ethylene polymers have a higher low shear/zero shear viscosity than the Comparative linear polymer, thus demonstrating that the copolymers of the invention have higher “green strength” which is useful for forming and maintaining blended compositions such as those used in the wire and cable coating industry, where the compounded materials must maintain their integrity at low or zero shear without segregating the components.

EXAMPLE 25 Comparative Example 27

Example 25 is an ethylene/1-octene elastic substantially linear ethylene polymer produced in a continuous solution polymerization process as described herein.

Comparative Example 27 is an ethylene/propene copolymer made by Mitsui PetroChemical Corporation and trademarked Tafmer™ P-0480. Table XII summarizes physical properties and rheological performance of these two polymers:

TABLE XII Comparative Property Example 25 Example 27 I₂ (g/10 minutes) 1.01 1.1 Density (g/cm³) 0.870 0.870 I₁₀/I₂ 7.62 6.06 M_(w)/M_(n) 1.98 1.90 PI (kPoise) 7.9 27.4 Elastic Modulus @ 0.1 964 567.7 rad/sec (dyne/cm²) OSMF*, critical shear rate 781 105 (sec⁻¹) *Onset of surface melt fracture

Even though Example 25 and Comparative Example 27 have similarly narrow molecular weight distributions (M_(w)/M_(n)), I₂ and density, Example 25 has a PI which is 28 percent of that of Comparative Example 27, a 743 percent of the shear rate at the onset of surface melt fracture and a higher elastic modulus than Comparative Example 27, demonstrating that Example 24 has much better processability than Comparative Example 27. Onset of surface melt fracture is easily identified by visually observing the surface extrudate and noting when the extrudate starts losing gloss and small surface roughness is detected by using 40×magnification.

EXAMPLES 28-37

Examples 28-35 are ethylene/propene copolymers made using the constrained geometry catalyst described herein and in a continuous solution polymerization process. Examples 36 and 37 are ethylene/1-butene copolymers made using the constrained geometry catalyst described herein and in a continuous solution polymerization process. Examples 28-37 each contained approximately 1250 ppm calcium strearate, 200 ppm Irganox 1010. These polymers did not, however, contain a secondary antioxidant (e.g. a phosphite). The low level of phenol (i.e. 200 ppm Irganox 1010) coupled with the lack of the secondary antioxidant may have contributed to the lower melt fracture performance of some of the polymers shown in Table XV. It is well known that thermally processing polyethylene polymers, especially in the presence of oxygen, can lead to oxidative crosslinking and extrusion variation, i.e. melt fracture. Table XIII and XIIIA describe the polymerization conditions and Table XIV describes the resultant polymer physical properties for Examples 28-35:

TABLE XIII Reactor ethylene Estimated conc. reactor PE Hydrogen/ (weight conc. (weight Ethylene flow ethylene ratio Ex. percent) percent) rate (lbs/hr) (mole percent) 28 5.3 6.0 3.19 0.048 29 4.2 7.3 3.19 0.024 30 4.0 8.9 3.19 0.028 31 3.5 9.3 3.18 0.024 32 2.5 10.6 3.20 0.027 33 2.6 10.7 3.18 0.007 34 1.3 10.5 3.19 0.027 35 1.0 10.9 3.19 0.010

TABLE XIIIA Diluent/ Ethylene ethylene Comonomer/olefin Ex. Reactor temp (C) Conversion % ratio ratio* 28 170 51 8.2 25.5 29 172 61 8.1 24.0 30 171 67 7.1 16.6 31 171 71 7.2 20.1 32 170 79 7.1 15.6 33 173 78 7.1 16.7 34 145 88 8.2 17.8 35 158 91 8.2 18.8 *Comonomer/total olefin ratio = percentage weight ratio of propene/(propene + ethylene).

TABLE XIV I₂ (gms/10 Density Ex. minutes) I₁₀/I₂ (gm/cm³) M_(w)/M_(n) 28 1.08 7.8 0.9176 2.00 29 1.02 8.8 0.9173 2.17 30 0.82 9.2 0.9175 2.08 31 0.79 9.4 0.9196 2.04 32 1.01 10.6 0.9217 2.09 33 0.83 12.4 0.9174 2.31 34 0.54 15.2 0.9201 2.12 35 0.62 15.6 0.9185 2.32

FIG. 7 graphically displays a best fit line drawn through a plot of the I₁₀/I₂ ratio for the ethylene/propene substantially linear polymers of Examples 28-35 as a function of ethylene concentration in the polymerization reactor. Surprisingly, in contrast to conventional Ziegler polymerized polymers and in contrast to a batch polymerization using the same catalyst and relatively high ethyelne concentrations, as the ethylene concentration in the reactor decreases using a continuous polymerization process, the I₁₀/I₂ ratio (indicating the amount of long chain branching in the novel substantially linear polymers) increases, even though the molecular weight distribution, M_(w)/M_(n), remains very narrow and essentially constant at about 2.

Table 15 shows the critical shear stress and critical shear rate at OGMF and OSMF for Examples 28-35:

TABLE XV Example OSMF OGMF 28 (shear stress) 2.15 × 10⁶ dyne/cm² 4.09 × 10⁶ dyne/cm² 28 (shear rate) 129.8 sec⁻¹ 668.34 sec⁻¹ 29 (shear stress) 1.94 × 10⁶ dyne/cm² 4.3 × 10⁶ dyne/cm² 29 (shear rate) 118.8 sec⁻¹ 652.1 sec⁻¹ 30 (shear stress) 1.08 × 10⁶ dyne/cm² 4.3 × 10⁶ dyne/cm² 30 (shear rate) 86.12 sec⁻¹ 650.7 sec⁻¹ 31 (shear stress) 1.08 × 10⁶ dyne/cm² >4.3 × 10⁶ dyne/cm² 31 (shear rate) 90.45 sec⁻¹ >6.83 sec⁻¹ 32 (shear stress) 1.94 × 10⁶ dyne/cm² 3.66 × 10⁶ dyne/cm² 32 (shear rate) 178.2 sec⁻¹ 673 sec⁻¹ 33 (shear stress) 2.15 × 10⁶ dyne/cm² about 3.23 × 10⁶ dyne/cm² 33 (shear rate) 235.7 sec⁻¹ about 591 sec⁻¹ 34 (shear stress) 1.94 × 10⁶ dyne/cm² 3.44 × 10⁶ dyne/cm² 34 (shear rate) 204.13 sec⁻¹ 725.23 sec⁻¹ 35 (shear stress) 1.94 × 10⁶ dyne/cm² about 3.26 × 10⁶ dyne/cm² 35 (shear rate) 274.46 sec⁻¹ 637.7 sec⁻¹

Table XVI and XVIA describe the polymerization conditions and Table XVII describes the resultant polymer physical properties for ethylenell-butene copolymer Examples 36 and 37:

TABLE XVI Reactor ethylene Reactor PE conc. conc Hydrogen/ (weight (weight Ethylene flow ethylene ratio Ex. percent) percent) rate (lbs/hr) (mole percent) 36 5.3 5.8 3.20 0.035 37 1.3 10.8 3.19 0.010

TABLE XVIA Ethylene Comonom Diluent/ Conversion er/olefin Ex. Reactor temp (C) Ethylene Ratio (%) ratio* 36 170 8.1 51 24.2 37 152 8.2 87 17.1 *Comonomer/total olefin ratio = percentage weight ratio of 1-butene/(1-butene + ethylene).

TABLE XVII I₂ (gms/10 Density Ex. minutes) I₁₀/I₂ (gm/cm³) M_(w)/M_(n) 36 0.59 7.5 0.9201 2.06 37 1.03 11.4 0.9146 2.22

The data in Tables XVI, XVIA and XVII show that as the ethylene concentration in the reactor decreases while using the constrained geometry catalyst as described herein, the I₁₀/I₂ ratio of the novel substantially linear polymers increases, indicating the amount of long chain branching in the novel polymers, even while the molecular weight distribution, M_(w)/M_(n), of the novel polymers remains narrow at essentially about 2.

Table XVIII shows the critical shear suss and critical shear rate at OGMF and OSMF for Examples 36 and 37:

TABLE XVIII Example OSMF OGMF 36 (shear stress) 1.94 × 10⁶ dyne/cm² 4.09 × 10⁶ dyne/cm² 36 (shear rate) 52.3 sec⁻¹ 234.45 sec⁻¹ 37 (shear stress) 1.08 × 10⁶ dyne/cm² 3.01 × 10⁶ dyne/cm² 37 (shear rate) 160.5 sec⁻¹ 493.9 sec⁻¹

Comparative Example 38

An ethylene polymer, as described in U.S. Pat. No. 5,218,071, is polymerized according to the teachings of that patent and tested for melt fracture properties.

All catalyst manipulations were performed under anhydrous, anaerobic conditions in an inert atmosphere box. The solvents, toluene and Isopar E, and the comonomer, octene-1, were thoroughly dried and deaerated beore use. poly(methylalurnioxane) (PMAO) was obtained from AKZO Chemicals Inc. as a 1.55 M Al in toluene solution and used as received The metallocene ethylenebis(indenyl)hafnium dichloride was obtained rom Schering A. G. as a solid. This metallocene is known to contain 0.2 weight percent Zirconium contamination. A slurry of the hafnium complex was prepared from this solid (0.253 g; 0.5 mmol; 0.010 M) and 50 mL toluene. The slurry was thoroughly stirred overnight prior to use.

A one gallon, stirred autoclave reactor was charged with Isopar E (2.1 L) and octene-1 (175 mL) and the contents heated to 80 C. Upon reaching temperature, a sample of the PMAO (26.8 mL; 40.0 mmol Al) in toluene was pressured into the reactor from a 75 mL cylinder using a nitrogen flush. After a few minutes, an aliquot of the metallocene slurry (4.0 mL; 0.040 mmol; Al:Hf=1000:1) was flushed into the reactor in a similar manner. Ethylene was continuously supplied to the reactor at a rate of 17 g/min to initiate polymerization. The ethylene flow was maintained for ten minutes and during the latter part of the polymerization the flow rate slowed as the pressure approached a setpoint of 100 psig. After this time, the ethylene supply was shut off and the contents of the reactor transferred by pressure to a glass resin kettle containing a small amount of antioxidant (0.30 g Irgaphos 168; 0.07 g rganox 1010). The solvent was slowly allowed to evaporate and the polymer obtained form the solution was dried under vacuum at 50 C. for 72 h. The yield of the product was 159 g or an efficiency of 3975 g PE/mmol Hf.

The recovered polymer had a M_(w)=1.341×10⁵, M_(n)=5.65×10⁴, M_(w)/M_(n)=2.373, density (measured in a gradien column)=0.8745 g/cc, I₂=0.63 g/10 min., I₁₀/I₂=15.9, and had two distinct melting peaks (as shown in FIG. 8). The polymer showed two peak melting points, one at 30.56 C. and the other at 102.55 C. The polymer also showed two peak crystallization points, one at 9.47 C. and the other at 81.61 C.

Melt fracture was determined using the GER at 190 C. with a die having a diameter of 0.0145 inches and an L/D=20. 

We claim:
 1. A fabricated article made from an ethylene polymer containing less than about 20 ppm aluminum, the polymer having: a) a melt flow ratio, I₁₀/I₂, ≧5.63, b) a molecular weight distribution, M_(w)/M_(n), defined by the equation: M_(w)/M_(n)≦(I₁₀/I₂)−4.63, and c) a critical shear stress at onset of gross melt fracture greater than about 4×10⁶ dyne/cm², and d) a single melting point as determined by differential scanning calorimetry between −30 C. and 150 C.
 2. A fabricated article made from an ethylene polymer containing less than about 20 ppm aluminum, the polymer having: a) a melt flow ratio, I₁₀/I₂, ≧5.63, b) a molecular weight distribution, M_(w)/M_(n), defined by the equation: M_(w)/M_(n)≦(I₁₀/I₂)−4.63, and c) a critical shear stress at onset of surface melt fracture at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a linear ethylene polymer having an I₂, M_(w)/M_(n) and density within ten percent of the ethylene polymer, and d) a single melting point as determined by differential scanning calorimetry between −30 C. and 150 C.
 3. A fabricated article made from an ethylene polymer containing less than about 20 ppm aluminum, the polymer having: a) a melt flow ratio, I₁₀/I₂, ≧5.63, b) a molecular weight distribution, M_(w)/M_(n) of from about 1.5 to about 2.5, and a single melting peak as determined by differential scanning calorimetry between −30 C. and 150 C.
 4. A fabricated article made from an ethylene polymer containing less than about 20 ppm aluminum, the polymer having: a) a melt flow ration, I₁₀/I₂, ≧5.63, b) a molecular weight distribution, M_(w)/M_(n) of from about 1.5 to about 2.5, and c) a critical shear stress at onset of surface melt fracture at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a linear ethylene polymer having an I₂, M_(w)/M_(n) and density within ten percent of the ethylene polymer, and d) a single melting peak as determined by differential scanning calorimetry between −30 C. and 150 C.
 5. A fabricated article made from an ethylene polymer containing less than abut 20 ppm aluminum, the polymer having (i) a critical shear rate at onset of surface melt fracture of at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a linear ethylene polymer having an I₂, M_(w)/M_(n) and density within ten percent of the ethylene polymer, and (ii) a single melting point as determined by differential scanning calorimetry between −30 C. and 150 C.
 6. A fabricated article made from a substantially linear ethylene polymer containing less than about 20 ppm aluminum, the polymer having: a) from about 0.01 to about 3 long chain branches/1000 total carbons and b) a critical shear stress at onset of gross melt fracture of greater than about 4×10⁶ dyne/cm², and c) a single melting point as determined by differential scanning calorimetry between −30 C. and 150 C.
 7. A fabricated article made from a substantially linear ethylene polymer containing less than about 20 ppm aluminum, the polymer having: (a) from about 0.01 to about 3 long chain branches/1000 total carbons, (b) a critical shear rate at onset of surface melt fracture of at least 50 percent greater than the critical shear rate at the onset of surface melt fracture of a linear ethylene polymer having an I₂, M_(w)/M_(n) and density within ten percent of the ethylene polymer, and (c) a single melting point as determined by differential scanning calorimetry between −30 C. and 150 C.
 8. A fabricated article made from a substantially linear ethylene polymer containing less than about 20 ppm aluminum, the polymer having: (a) from about 0.01 to about 3 long chain branches/1000 total carbons, (b) a melt flow ratio, I₁₀/I₂≧5.63, and (c) a molecular weight distribution, M_(w)/M_(n) from about 1.5 to about 2.5, and (d) a single melting point as determined by differential scanning calorimetry between −30 C. and 150 C.
 9. The fabricated article of any of claims 1-8, wherein the ethylene polymer is selected from the group consisting of: (A) an ethylene homopolymer, or (B) an interpolymer of ethylene with at least one C₄-C₁₈ diolefin.
 10. The fabricated article of any of claims 1-8, wherein the ethylene polymer is selected from the group consisting of: (A) an ethylene homopolymer, and (B) an interpolymer of ethylene with at least one C₃-C₂₀ alpha-olefin.
 11. The article of any of claims 1-8 fabricated into a film.
 12. The article of any of claims 1-8 fabricated into a fiber.
 13. The fabricated article of any of claims 1-8 made by a molding process. 